| blob | eba864be96e8219f92c3bc9e1e737228f48e65e1 |
1 /* Graphical user interface functions for the Microsoft W32 API.
2 Copyright (C) 1989, 92, 93, 94, 95, 1996, 1997, 1998, 1999, 2000, 2001
3 Free Software Foundation, Inc.
5 This file is part of GNU Emacs.
7 GNU Emacs is free software; you can redistribute it and/or modify
8 it under the terms of the GNU General Public License as published by
9 the Free Software Foundation; either version 2, or (at your option)
10 any later version.
12 GNU Emacs is distributed in the hope that it will be useful,
13 but WITHOUT ANY WARRANTY; without even the implied warranty of
14 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 GNU General Public License for more details.
17 You should have received a copy of the GNU General Public License
18 along with GNU Emacs; see the file COPYING. If not, write to
19 the Free Software Foundation, Inc., 59 Temple Place - Suite 330,
20 Boston, MA 02111-1307, USA. */
22 /* Added by Kevin Gallo */
24 #include <config.h>
26 #include <signal.h>
27 #include <stdio.h>
28 #include <limits.h>
29 #include <errno.h>
51 #include <commdlg.h>
52 #include <shellapi.h>
53 #include <ctype.h>
64 /* A definition of XColor for non-X frames. */
65 #ifndef HAVE_X_WINDOWS
72 #endif
76 /* The gray bitmap `bitmaps/gray'. This is done because w32term.c uses
77 it, and including `bitmaps/gray' more than once is a problem when
78 config.h defines `static' as an empty replacement string. */
84 /* The colormap for converting color names to RGB values */
85 Lisp_Object Vw32_color_map;
87 /* Non nil if alt key presses are passed on to Windows. */
88 Lisp_Object Vw32_pass_alt_to_system;
90 /* Non nil if alt key is translated to meta_modifier, nil if it is translated
91 to alt_modifier. */
92 Lisp_Object Vw32_alt_is_meta;
94 /* If non-zero, the windows virtual key code for an alternative quit key. */
95 Lisp_Object Vw32_quit_key;
97 /* Non nil if left window key events are passed on to Windows (this only
98 affects whether "tapping" the key opens the Start menu). */
99 Lisp_Object Vw32_pass_lwindow_to_system;
101 /* Non nil if right window key events are passed on to Windows (this
102 only affects whether "tapping" the key opens the Start menu). */
103 Lisp_Object Vw32_pass_rwindow_to_system;
105 /* Virtual key code used to generate "phantom" key presses in order
106 to stop system from acting on Windows key events. */
107 Lisp_Object Vw32_phantom_key_code;
109 /* Modifier associated with the left "Windows" key, or nil to act as a
110 normal key. */
111 Lisp_Object Vw32_lwindow_modifier;
113 /* Modifier associated with the right "Windows" key, or nil to act as a
114 normal key. */
115 Lisp_Object Vw32_rwindow_modifier;
117 /* Modifier associated with the "Apps" key, or nil to act as a normal
118 key. */
119 Lisp_Object Vw32_apps_modifier;
121 /* Value is nil if Num Lock acts as a function key. */
122 Lisp_Object Vw32_enable_num_lock;
124 /* Value is nil if Caps Lock acts as a function key. */
125 Lisp_Object Vw32_enable_caps_lock;
127 /* Modifier associated with Scroll Lock, or nil to act as a normal key. */
128 Lisp_Object Vw32_scroll_lock_modifier;
130 /* Switch to control whether we inhibit requests for synthesized bold
131 and italic versions of fonts. */
134 /* Enable palette management. */
135 Lisp_Object Vw32_enable_palette;
137 /* Control how close left/right button down events must be to
138 be converted to a middle button down event. */
139 Lisp_Object Vw32_mouse_button_tolerance;
141 /* Minimum interval between mouse movement (and scroll bar drag)
142 events that are passed on to the event loop. */
143 Lisp_Object Vw32_mouse_move_interval;
145 /* Flag to indicate if XBUTTON events should be passed on to Windows. */
148 /* The name we're using in resource queries. */
149 Lisp_Object Vx_resource_name;
151 /* Non nil if no window manager is in use. */
152 Lisp_Object Vx_no_window_manager;
154 /* Non-zero means we're allowed to display a hourglass pointer. */
158 /* The background and shape of the mouse pointer, and shape when not
159 over text or in the modeline. */
164 /* The shape when over mouse-sensitive text. */
166 Lisp_Object Vx_sensitive_text_pointer_shape;
168 /* Color of chars displayed in cursor box. */
170 Lisp_Object Vx_cursor_fore_pixel;
172 /* Nonzero if using Windows. */
176 /* Search path for bitmap files. */
178 Lisp_Object Vx_bitmap_file_path;
180 /* Regexp matching a font name whose width is the same as `PIXEL_SIZE'. */
182 Lisp_Object Vx_pixel_size_width_font_regexp;
184 /* Alist of bdf fonts and the files that define them. */
185 Lisp_Object Vw32_bdf_filename_alist;
187 /* A flag to control whether fonts are matched strictly or not. */
190 /* A flag to control whether we should only repaint if GetUpdateRect
191 indicates there is an update region. */
194 /* Associative list linking character set strings to Windows codepages. */
195 Lisp_Object Vw32_charset_info_alist;
197 /* VIETNAMESE_CHARSET is not defined in some versions of MSVC. */
198 #ifndef VIETNAMESE_CHARSET
199 #define VIETNAMESE_CHARSET 163
200 #endif
202 Lisp_Object Qauto_raise;
203 Lisp_Object Qauto_lower;
204 Lisp_Object Qbar;
205 Lisp_Object Qborder_color;
206 Lisp_Object Qborder_width;
207 Lisp_Object Qbox;
208 Lisp_Object Qcursor_color;
209 Lisp_Object Qcursor_type;
210 Lisp_Object Qgeometry;
211 Lisp_Object Qicon_left;
212 Lisp_Object Qicon_top;
213 Lisp_Object Qicon_type;
214 Lisp_Object Qicon_name;
215 Lisp_Object Qinternal_border_width;
216 Lisp_Object Qleft;
217 Lisp_Object Qright;
218 Lisp_Object Qmouse_color;
219 Lisp_Object Qnone;
220 Lisp_Object Qparent_id;
221 Lisp_Object Qscroll_bar_width;
222 Lisp_Object Qsuppress_icon;
223 Lisp_Object Qundefined_color;
224 Lisp_Object Qvertical_scroll_bars;
225 Lisp_Object Qvisibility;
226 Lisp_Object Qwindow_id;
227 Lisp_Object Qx_frame_parameter;
228 Lisp_Object Qx_resource_name;
229 Lisp_Object Quser_position;
230 Lisp_Object Quser_size;
231 Lisp_Object Qscreen_gamma;
232 Lisp_Object Qline_spacing;
233 Lisp_Object Qcenter;
234 Lisp_Object Qcancel_timer;
235 Lisp_Object Qhyper;
236 Lisp_Object Qsuper;
237 Lisp_Object Qmeta;
238 Lisp_Object Qalt;
239 Lisp_Object Qctrl;
240 Lisp_Object Qcontrol;
241 Lisp_Object Qshift;
243 Lisp_Object Qw32_charset_ansi;
244 Lisp_Object Qw32_charset_default;
245 Lisp_Object Qw32_charset_symbol;
246 Lisp_Object Qw32_charset_shiftjis;
247 Lisp_Object Qw32_charset_hangeul;
248 Lisp_Object Qw32_charset_gb2312;
249 Lisp_Object Qw32_charset_chinesebig5;
250 Lisp_Object Qw32_charset_oem;
252 #ifndef JOHAB_CHARSET
253 #define JOHAB_CHARSET 130
254 #endif
255 #ifdef JOHAB_CHARSET
256 Lisp_Object Qw32_charset_easteurope;
257 Lisp_Object Qw32_charset_turkish;
258 Lisp_Object Qw32_charset_baltic;
259 Lisp_Object Qw32_charset_russian;
260 Lisp_Object Qw32_charset_arabic;
261 Lisp_Object Qw32_charset_greek;
262 Lisp_Object Qw32_charset_hebrew;
263 Lisp_Object Qw32_charset_vietnamese;
264 Lisp_Object Qw32_charset_thai;
265 Lisp_Object Qw32_charset_johab;
266 Lisp_Object Qw32_charset_mac;
267 #endif
269 #ifdef UNICODE_CHARSET
270 Lisp_Object Qw32_charset_unicode;
271 #endif
273 Lisp_Object Qfullscreen;
274 Lisp_Object Qfullwidth;
275 Lisp_Object Qfullheight;
276 Lisp_Object Qfullboth;
282 /* State variables for emulating a three button mouse. */
283 #define LMOUSE 1
284 #define MMOUSE 2
285 #define RMOUSE 4
293 /* Window that is tracking the mouse. */
295 FARPROC track_mouse_event_fn;
297 /* W95 mousewheel handler */
300 /* Timers */
301 #define MOUSE_BUTTON_ID 1
302 #define MOUSE_MOVE_ID 2
303 #define MENU_FREE_ID 3
304 /* The delay (milliseconds) before a menu is freed after WM_EXITMENULOOP
305 is received. */
306 #define MENU_FREE_DELAY 1000
309 /* The below are defined in frame.c. */
317 Lisp_Object Qface_set_after_frame_default;
319 #ifdef GLYPH_DEBUG
321 #endif
324 /* From w32term.c. */
337 \f
338 /* Error if we are not connected to MS-Windows. */
339 void
341 {
344 }
346 /* Nonzero if we can use mouse menus.
347 You should not call this unless HAVE_MENUS is defined. */
349 int
351 {
353 }
355 /* Extract a frame as a FRAME_PTR, defaulting to the selected frame
356 and checking validity for W32. */
358 FRAME_PTR
360 Lisp_Object frame;
361 {
362 FRAME_PTR f;
371 }
373 /* Let the user specify an display with a frame.
374 nil stands for the selected frame--or, if that is not a w32 frame,
375 the first display on the list. */
379 Lisp_Object frame;
380 {
382 {
387 else
389 }
392 else
393 {
394 FRAME_PTR f;
401 }
402 }
403 \f
404 /* Return the Emacs frame-object corresponding to an w32 window.
405 It could be the frame's main window or an icon window. */
407 /* This function can be called during GC, so use GC_xxx type test macros. */
412 HWND wdesc;
413 {
418 {
430 }
432 }
434 \f
436 /* Code to deal with bitmaps. Bitmaps are referenced by their bitmap
437 id, which is just an int that this section returns. Bitmaps are
438 reference counted so they can be shared among frames.
440 Bitmap indices are guaranteed to be > 0, so a negative number can
441 be used to indicate no bitmap.
443 If you use x_create_bitmap_from_data, then you must keep track of
444 the bitmaps yourself. That is, creating a bitmap from the same
445 data more than once will not be caught. */
448 /* Functions to access the contents of a bitmap, given an id. */
450 int
452 FRAME_PTR f;
454 {
456 }
458 int
460 FRAME_PTR f;
462 {
464 }
466 int
468 FRAME_PTR f;
470 {
472 }
475 /* Allocate a new bitmap record. Returns index of new record. */
477 static int
479 FRAME_PTR f;
480 {
485 {
487 dpyinfo->bitmaps
488 = (struct w32_bitmap_record *) xmalloc (dpyinfo->bitmaps_size * sizeof (struct w32_bitmap_record));
491 }
501 dpyinfo->bitmaps
505 }
507 /* Add one reference to the reference count of the bitmap with id ID. */
509 void
511 FRAME_PTR f;
513 {
515 }
517 /* Create a bitmap for frame F from a HEIGHT x WIDTH array of bits at BITS. */
519 int
524 {
526 Pixmap bitmap;
532 bits);
547 }
549 /* Create bitmap from file FILE for frame F. */
551 int
554 Lisp_Object file;
555 {
560 HBITMAP bitmap;
562 Lisp_Object found;
565 HINSTANCE hinst;
567 /* Look for an existing bitmap with the same name. */
569 {
573 {
576 }
577 }
579 /* Search bitmap-file-path for the file, if appropriate. */
609 }
611 /* Remove reference to bitmap with id number ID. */
613 void
615 FRAME_PTR f;
617 {
621 {
624 {
625 BLOCK_INPUT;
628 {
631 }
632 UNBLOCK_INPUT;
633 }
634 }
635 }
637 /* Free all the bitmaps for the display specified by DPYINFO. */
639 static void
642 {
646 {
650 }
652 }
653 \f
654 /* Connect the frame-parameter names for W32 frames
655 to the ways of passing the parameter values to the window system.
657 The name of a parameter, as a Lisp symbol,
658 has an `x-frame-parameter' property which is an integer in Lisp
659 but can be interpreted as an `enum x_frame_parm' in C. */
661 enum x_frame_parm
662 {
663 X_PARM_FOREGROUND_COLOR,
664 X_PARM_BACKGROUND_COLOR,
665 X_PARM_MOUSE_COLOR,
666 X_PARM_CURSOR_COLOR,
667 X_PARM_BORDER_COLOR,
668 X_PARM_ICON_TYPE,
669 X_PARM_FONT,
670 X_PARM_BORDER_WIDTH,
671 X_PARM_INTERNAL_BORDER_WIDTH,
672 X_PARM_NAME,
673 X_PARM_AUTORAISE,
674 X_PARM_AUTOLOWER,
675 X_PARM_VERT_SCROLL_BAR,
676 X_PARM_VISIBILITY,
677 X_PARM_MENU_BAR_LINES
678 };
681 struct x_frame_parm_table
682 {
685 };
692 /* TODO: Native Input Method support; see x_create_im. */
707 Lisp_Object));
712 Lisp_Object));
721 Lisp_Object));
724 {
751 };
753 /* Attach the `x-frame-parameter' properties to
754 the Lisp symbol names of parameters relevant to W32. */
756 void
758 {
764 }
765 \f
766 /* Really try to move where we want to be in case of fullscreen. Some WMs
767 moves the window where we tell them. Some (mwm, twm) moves the outer
768 window manager window there instead.
769 Try to compensate for those WM here. */
770 static void
775 {
778 {
784 }
785 }
787 /* Change the parameters of frame F as specified by ALIST.
788 If a parameter is not specially recognized, do nothing;
789 otherwise call the `x_set_...' function for that parameter. */
791 void
793 FRAME_PTR f;
794 Lisp_Object alist;
795 {
796 Lisp_Object tail;
798 /* If both of these parameters are present, it's more efficient to
799 set them both at once. So we wait until we've looked at the
800 entire list before we set them. */
803 /* Same here. */
806 /* Same with these. */
809 /* Record in these vectors all the parms specified. */
821 i++;
826 /* Extract parm names and values into those vectors. */
830 {
831 Lisp_Object elt;
836 i++;
837 }
838 /* TAIL and ALIST are not used again below here. */
845 /* There is no need to gcpro LEFT, TOP, ICON_LEFT, or ICON_TOP,
846 because their values appear in VALUES and strings are not valid. */
850 /* Provide default values for HEIGHT and WIDTH. */
853 else
858 else
861 /* Process foreground_color and background_color before anything else.
862 They are independent of other properties, but other properties (e.g.,
863 cursor_color) are dependent upon them. */
864 /* Process default font as well, since fringe widths depends on it. */
866 {
875 {
882 {
890 }
891 }
892 }
894 /* Now process them in reverse of specified order. */
896 {
918 /* Processed above. */
920 else
921 {
933 }
934 }
936 /* Don't die if just one of these was set. */
938 {
942 else
944 }
946 {
950 else
952 }
954 /* If one of the icon positions was not set, preserve or default it. */
956 {
961 }
963 {
968 }
971 {
972 /* If the frame is visible already and the fullscreen parameter is
973 being set, it is too late to set WM manager hints to specify
974 size and position.
975 Here we first get the width, height and position that applies to
976 fullscreen. We then move the frame to the appropriate
977 position. Resize of the frame is taken care of in the code after
978 this if-statement. */
983 }
985 /* Don't set these parameters unless they've been explicitly
986 specified. The window might be mapped or resized while we're in
987 this function, and we don't want to override that unless the lisp
988 code has asked for it.
990 Don't set these parameters unless they actually differ from the
991 window's current parameters; the window may not actually exist
992 yet. */
993 {
994 Lisp_Object frame;
1009 {
1013 /* Record the signs. */
1018 {
1022 }
1026 {
1029 }
1033 {
1035 }
1040 {
1044 }
1048 {
1051 }
1055 {
1057 }
1060 /* Store the numeric value of the position. */
1066 /* Actually set that position, and convert to absolute. */
1068 }
1073 }
1075 UNGCPRO;
1076 }
1078 /* Store the screen positions of frame F into XPTR and YPTR.
1079 These are the positions of the containing window manager window,
1080 not Emacs's own window. */
1082 void
1084 FRAME_PTR f;
1086 {
1087 POINT pt;
1088 RECT rect;
1098 /* Remember x_pixels_diff and y_pixels_diff. */
1104 }
1106 /* Insert a description of internally-recorded parameters of frame X
1107 into the parameter alist *ALISTPTR that is to be given to the user.
1108 Only parameters that are specific to W32
1109 and whose values are not correctly recorded in the frame's
1110 param_alist need to be considered here. */
1112 void
1116 {
1118 Lisp_Object tem;
1120 /* Represent negative positions (off the top or left screen edge)
1121 in a way that Fmodify_frame_parameters will understand correctly. */
1125 else
1131 else
1156 }
1157 \f
1162 This adds or updates a named color to w32-color-map, making it
1163 available for use. The original entry's RGB ref is returned, or nil
1167 {
1168 Lisp_Object rgb;
1170 Lisp_Object entry;
1179 BLOCK_INPUT;
1181 /* replace existing entry in w32-color-map or add new entry. */
1184 {
1187 }
1188 else
1189 {
1192 }
1194 UNBLOCK_INPUT;
1197 }
1202 Assign this value to w32-color-map to replace the existing color map.
1204 The file should define one named RGB color per line like so:
1205 R G B name
1208 Lisp_Object filename;
1209 {
1212 Lisp_Object abspath;
1219 {
1224 BLOCK_INPUT;
1228 {
1235 cmap);
1236 }
1237 }
1240 UNBLOCK_INPUT;
1241 }
1244 }
1246 /* The default colors for the w32 color map */
1248 {
1250 COLORREF colorref;
1253 colormap_t w32_color_map[] =
1254 {
1495 };
1499 ()
1500 {
1503 Lisp_Object cmap;
1505 BLOCK_INPUT;
1513 cmap);
1515 UNBLOCK_INPUT;
1518 }
1520 Lisp_Object
1522 Lisp_Object rgb;
1523 {
1524 Lisp_Object color;
1528 BLOCK_INPUT;
1532 UNBLOCK_INPUT;
1536 else
1538 }
1540 COLORREF
1543 {
1546 BLOCK_INPUT;
1549 {
1558 {
1561 }
1563 QUIT;
1564 }
1567 UNBLOCK_INPUT;
1570 }
1572 COLORREF
1575 {
1578 BLOCK_INPUT;
1581 {
1582 /* Could be an old-style RGB Device specification. */
1589 {
1590 UINT colorval;
1597 {
1602 /* The check for 'x' in the following conditional takes into
1603 account the fact that strtol allows a "0x" in front of
1604 our numbers, and we don't. */
1614 {
1626 }
1630 {
1631 UNBLOCK_INPUT;
1633 }
1635 }
1636 }
1637 }
1639 {
1641 UINT colorval;
1648 {
1652 /* The check for 'x' in the following conditional takes into
1653 account the fact that strtol allows a "0x" in front of
1654 our numbers, and we don't. */
1661 {
1675 }
1681 {
1684 UNBLOCK_INPUT;
1686 }
1690 }
1691 }
1693 {
1694 /* This is an RGB Intensity specification. */
1696 UINT colorval;
1703 {
1706 UINT val;
1714 /* We used 0x100 instead of 0xFF to give an continuous
1715 range between 0.0 and 1.0 inclusive. The next statement
1716 fixes the 1.0 case. */
1722 {
1725 UNBLOCK_INPUT;
1727 }
1731 }
1732 }
1733 /* I am not going to attempt to handle any of the CIE color schemes
1734 or TekHVC, since I don't know the algorithms for conversion to
1735 RGB. */
1737 /* If we fail to lookup the color name in w32_color_map, then check the
1738 colorname to see if it can be crudely approximated: If the X color
1739 ends in a number (e.g., "darkseagreen2"), strip the number and
1740 return the result of looking up the base color name. */
1743 {
1747 {
1756 }
1757 }
1759 UNBLOCK_INPUT;
1761 }
1764 void
1766 {
1769 HPALETTE new_palette;
1772 /* don't bother trying to create palette if not supported */
1796 /* Realize display palette and garbage all frames. */
1800 }
1802 #define W32_COLOR(pe) RGB (pe.peRed, pe.peGreen, pe.peBlue)
1803 #define SET_W32_COLOR(pe, color) \
1804 do \
1805 { \
1806 pe.peRed = GetRValue (color); \
1807 pe.peGreen = GetGValue (color); \
1808 pe.peBlue = GetBValue (color); \
1809 pe.peFlags = 0; \
1810 } while (0)
1812 #if 0
1813 /* Keep these around in case we ever want to track color usage. */
1814 void
1816 {
1822 /* check if color is already mapped */
1824 {
1826 {
1829 }
1831 }
1833 /* not already mapped, so add to list and recreate Windows palette */
1842 /* set flag that palette must be regenerated */
1844 }
1846 void
1848 {
1855 /* check if color is already mapped */
1857 {
1859 {
1861 {
1866 }
1867 else
1869 }
1872 }
1874 /* set flag that palette must be regenerated */
1876 }
1877 #endif
1880 /* Gamma-correct COLOR on frame F. */
1882 void
1886 {
1888 {
1893 }
1894 }
1897 /* Decide if color named COLOR is valid for the display associated with
1898 the selected frame; if so, return the rgb values in COLOR_DEF.
1899 If ALLOC is nonzero, allocate a new colormap cell. */
1901 int
1903 FRAME_PTR f;
1907 {
1909 COLORREF w32_color_ref;
1914 {
1916 {
1917 /* Apply gamma correction. */
1921 }
1923 /* Map this color to the palette if it is enabled. */
1925 {
1931 /* check if color is already mapped */
1933 {
1938 }
1941 {
1942 /* not already mapped, so add to list */
1950 /* set flag that palette must be regenerated */
1952 }
1953 }
1954 /* Ensure COLORREF value is snapped to nearest color in (default)
1955 palette by simulating the PALETTERGB macro. This works whether
1956 or not the display device has a palette. */
1965 }
1966 else
1967 {
1969 }
1970 }
1972 /* Given a string ARG naming a color, compute a pixel value from it
1973 suitable for screen F.
1974 If F is not a color screen, return DEF (default) regardless of what
1975 ARG says. */
1977 int
1979 FRAME_PTR f;
1980 Lisp_Object arg;
1982 {
1983 XColor cdef;
1995 /* w32_defined_color is responsible for coping with failures
1996 by looking for a near-miss. */
2000 /* defined_color failed; return an ultimate default. */
2002 }
2003 \f
2004 /* Change the `line-spacing' frame parameter of frame F. OLD_VALUE is
2005 the previous value of that parameter, NEW_VALUE is the new value. */
2007 static void
2011 {
2016 else
2021 }
2024 /* Change the `fullscreen' frame parameter of frame F. OLD_VALUE is
2025 the previous value of that parameter, NEW_VALUE is the new value. */
2027 static void
2031 {
2040 }
2043 /* Change the `screen-gamma' frame parameter of frame F. OLD_VALUE is
2044 the previous value of that parameter, NEW_VALUE is the new value. */
2046 static void
2050 {
2054 /* The value 0.4545 is the normal viewing gamma. */
2056 else
2061 }
2064 /* Functions called only from `x_set_frame_param'
2065 to set individual parameters.
2067 If FRAME_W32_WINDOW (f) is 0,
2068 the frame is being created and its window does not exist yet.
2069 In that case, just record the parameter's new value
2070 in the standard place; do not attempt to change the window. */
2072 void
2076 {
2085 {
2092 }
2093 }
2095 void
2099 {
2104 {
2112 }
2113 }
2115 void
2119 {
2129 /* Don't let pointers be invisible. */
2135 BLOCK_INPUT;
2137 /* It's not okay to crash if the user selects a screwy cursor. */
2141 {
2144 }
2145 else
2150 {
2154 }
2155 else
2160 {
2164 }
2165 else
2171 {
2175 }
2176 else
2181 {
2183 cross_cursor
2186 }
2187 else
2191 {
2193 horizontal_drag_cursor
2196 }
2197 else
2198 horizontal_drag_cursor
2201 /* Check and report errors with the above calls. */
2205 {
2228 }
2258 UNBLOCK_INPUT;
2262 }
2264 /* Defined in w32term.c. */
2267 void
2271 {
2277 else
2282 /* Make sure that the cursor color differs from the background color. */
2284 {
2288 }
2294 {
2296 {
2299 }
2300 }
2303 }
2305 /* Set the border-color of frame F to pixel value PIX.
2306 Note that this does not fully take effect if done before
2307 F has an window. */
2308 void
2312 {
2316 {
2319 }
2320 }
2322 /* Set the border-color of frame F to value described by ARG.
2323 ARG can be a string naming a color.
2324 The border-color is used for the border that is drawn by the server.
2325 Note that this does not fully take effect if done before
2326 F has a window; it must be redone when the window is created. */
2328 void
2332 {
2339 }
2341 /* Value is the internal representation of the specified cursor type
2342 ARG. If type is BAR_CURSOR, return in *WIDTH the specified width
2343 of the bar cursor. */
2345 enum text_cursor_kinds
2347 Lisp_Object arg;
2349 {
2353 {
2356 }
2361 {
2364 }
2367 else
2368 /* Treat anything unknown as "box cursor".
2369 It was bad to signal an error; people have trouble fixing
2370 .Xdefaults with Emacs, when it has something bad in it. */
2374 }
2376 void
2378 FRAME_PTR f;
2380 {
2386 /* Make sure the cursor gets redrawn. This is overkill, but how
2387 often do people change cursor types? */
2388 update_mode_lines++;
2389 }
2390 \f
2391 void
2395 {
2408 BLOCK_INPUT;
2412 {
2413 UNBLOCK_INPUT;
2415 }
2417 UNBLOCK_INPUT;
2418 }
2420 /* Return non-nil if frame F wants a bitmap icon. */
2422 Lisp_Object
2424 FRAME_PTR f;
2425 {
2426 Lisp_Object tem;
2431 else
2433 }
2435 void
2439 {
2441 {
2444 }
2450 #if 0
2454 BLOCK_INPUT;
2464 {
2465 UNBLOCK_INPUT;
2467 }
2469 /* If the window was unmapped (and its icon was mapped),
2470 the new icon is not mapped, so map the window in its stead. */
2472 {
2473 #ifdef USE_X_TOOLKIT
2475 #endif
2477 }
2480 UNBLOCK_INPUT;
2481 #endif
2482 }
2487 void
2491 {
2492 Lisp_Object result;
2493 Lisp_Object fontset_name;
2494 Lisp_Object frame;
2501 BLOCK_INPUT;
2505 UNBLOCK_INPUT;
2512 {
2514 {
2515 /* Fontset names are built from ASCII font names, so the
2516 names may be equal despite there was a change. */
2519 }
2525 }
2526 else
2531 /* Don't call `face-set-after-frame-default' when faces haven't been
2532 initialized yet. This is the case when called from
2533 Fx_create_frame. In that case, the X widget or window doesn't
2534 exist either, and we can end up in x_report_frame_params with a
2535 null widget which gives a segfault. */
2537 {
2540 }
2541 }
2543 static void
2547 {
2549 }
2551 void
2555 {
2565 }
2567 void
2571 {
2583 {
2587 }
2588 else
2590 }
2592 void
2596 {
2597 Lisp_Object frame;
2604 else
2606 }
2608 \f
2609 /* Change window heights in windows rooted in WINDOW by N lines. */
2611 static void
2613 Lisp_Object window;
2615 {
2626 /* Handle just the top child in a vertical split. */
2630 /* Adjust all children in a horizontal split. */
2632 {
2635 }
2636 }
2638 void
2642 {
2646 /* Right now, menu bars don't work properly in minibuf-only frames;
2647 most of the commands try to apply themselves to the minibuffer
2648 frame itself, and get an error because you can't switch buffers
2649 in or split the minibuffer window. */
2655 else
2661 else
2662 {
2667 /* Adjust the frame size so that the client (text) dimensions
2668 remain the same. This depends on FRAME_EXTERNAL_MENU_BAR being
2669 set correctly. */
2672 }
2674 }
2677 /* Set the number of lines used for the tool bar of frame F to VALUE.
2678 VALUE not an integer, or < 0 means set the lines to zero. OLDVAL
2679 is the old number of tool bar lines. This function changes the
2680 height of all windows on frame F to match the new tool bar height.
2681 The frame's height doesn't change. */
2683 void
2687 {
2689 Lisp_Object root_window;
2691 /* Treat tool bars like menu bars. */
2695 /* Use VALUE only if an integer >= 0. */
2698 else
2701 /* Make sure we redisplay all windows in this frame. */
2706 /* Don't resize the tool-bar to more than we have room for. */
2710 {
2713 }
2719 /* We also have to make sure that the internal border at the top of
2720 the frame, below the menu bar or tool bar, is redrawn when the
2721 tool bar disappears. This is so because the internal border is
2722 below the tool bar if one is displayed, but is below the menu bar
2723 if there isn't a tool bar. The tool bar draws into the area
2724 below the menu bar. */
2726 {
2731 }
2733 /* If the tool bar gets smaller, the internal border below it
2734 has to be cleared. It was formerly part of the display
2735 of the larger tool bar, and updating windows won't clear it. */
2737 {
2742 BLOCK_INPUT;
2743 {
2747 }
2748 UNBLOCK_INPUT;
2752 }
2753 }
2756 /* Change the name of frame F to NAME. If NAME is nil, set F's name to
2757 w32_id_name.
2759 If EXPLICIT is non-zero, that indicates that lisp code is setting the
2760 name; if NAME is a string, set F's name to NAME and set
2761 F->explicit_name; if NAME is Qnil, then clear F->explicit_name.
2763 If EXPLICIT is zero, that indicates that Emacs redisplay code is
2764 suggesting a new name, which lisp code should override; if
2765 F->explicit_name is set, ignore the new name; otherwise, set it. */
2767 void
2770 Lisp_Object name;
2772 {
2773 /* Make sure that requests from lisp code override requests from
2774 Emacs redisplay code. */
2776 {
2777 /* If we're switching from explicit to implicit, we had better
2778 update the mode lines and thereby update the title. */
2783 }
2787 /* If NAME is nil, set the name to the w32_id_name. */
2789 {
2790 /* Check for no change needed in this very common case
2791 before we do any consing. */
2796 }
2797 else
2800 /* Don't change the name if it's already NAME. */
2806 /* For setting the frame title, the title parameter should override
2807 the name parameter. */
2812 {
2816 BLOCK_INPUT;
2818 UNBLOCK_INPUT;
2819 }
2820 }
2822 /* This function should be called when the user's lisp code has
2823 specified a name for the frame; the name will override any set by the
2824 redisplay code. */
2825 void
2827 FRAME_PTR f;
2829 {
2831 }
2833 /* This function should be called by Emacs redisplay code to set the
2834 name; names set this way will never override names set by the user's
2835 lisp code. */
2836 void
2838 FRAME_PTR f;
2840 {
2842 }
2843 \f
2844 /* Change the title of frame F to NAME.
2845 If NAME is nil, use the frame name as the title.
2847 If EXPLICIT is non-zero, that indicates that lisp code is setting the
2848 name; if NAME is a string, set F's name to NAME and set
2849 F->explicit_name; if NAME is Qnil, then clear F->explicit_name.
2851 If EXPLICIT is zero, that indicates that Emacs redisplay code is
2852 suggesting a new name, which lisp code should override; if
2853 F->explicit_name is set, ignore the new name; otherwise, set it. */
2855 void
2859 {
2860 /* Don't change the title if it's already NAME. */
2872 {
2876 BLOCK_INPUT;
2878 UNBLOCK_INPUT;
2879 }
2880 }
2881 \f
2882 void
2886 {
2888 }
2890 void
2894 {
2896 }
2898 void
2902 {
2904 }
2906 void
2910 {
2915 {
2917 vertical_scroll_bar_none :
2918 /* Put scroll bars on the right by default, as is conventional
2919 on MS-Windows. */
2921 ? vertical_scroll_bar_left
2924 /* We set this parameter before creating the window for the
2925 frame, so we can get the geometry right from the start.
2926 However, if the window hasn't been created yet, we shouldn't
2927 call x_set_window_size. */
2931 }
2932 }
2934 void
2938 {
2942 {
2949 }
2952 {
2959 }
2963 }
2964 \f
2965 /* Subroutines of creating an frame. */
2967 /* Make sure that Vx_resource_name is set to a reasonable value.
2968 Fix it up, or set it to `emacs' if it is too hopeless. */
2970 static void
2972 {
2974 /* Number of valid characters in the resource name. */
2976 /* Number of invalid characters in the resource name. */
2982 {
2988 /* Only letters, digits, - and _ are valid in resource names.
2989 Count the valid characters and count the invalid ones. */
2991 {
2997 bad_count++;
2998 else
2999 good_count++;
3000 }
3001 }
3002 else
3003 /* Not a string => completely invalid. */
3006 /* If name is valid already, return. */
3010 /* If name is entirely invalid, or nearly so, use `emacs'. */
3013 {
3016 }
3018 /* Name is partly valid. Copy it and replace the invalid characters
3019 with underscores. */
3024 {
3031 }
3032 }
3039 This uses `INSTANCE.ATTRIBUTE' as the key and `Emacs.CLASS' as the
3040 class, where INSTANCE is the name under which Emacs was invoked, or
3041 the name specified by the `-name' or `-rn' command-line arguments.
3043 The optional arguments COMPONENT and SUBCLASS add to the key and the
3044 class, respectively. You must specify both of them or neither.
3045 If you specify them, the key is `INSTANCE.COMPONENT.ATTRIBUTE'
3049 {
3066 /* Allocate space for the components, the dots which separate them,
3067 and the final '\0'. Make them big enough for the worst case. */
3080 /* Start with emacs.FRAMENAME for the name (the specific one)
3081 and with `Emacs' for the class key (the general one). */
3089 {
3095 }
3105 else
3107 }
3109 /* Used when C code wants a resource value. */
3114 {
3119 /* Allocate space for the components, the dots which separate them,
3120 and the final '\0'. */
3128 attribute);
3132 }
3134 /* Types we might convert a resource string into. */
3135 enum resource_types
3136 {
3137 RES_TYPE_NUMBER,
3138 RES_TYPE_FLOAT,
3139 RES_TYPE_BOOLEAN,
3140 RES_TYPE_STRING,
3141 RES_TYPE_SYMBOL
3142 };
3144 /* Return the value of parameter PARAM.
3146 First search ALIST, then Vdefault_frame_alist, then the X defaults
3147 database, using ATTRIBUTE as the attribute name and CLASS as its class.
3149 Convert the resource to the type specified by desired_type.
3151 If no default is specified, return Qunbound. If you call
3152 w32_get_arg, make sure you deal with Qunbound in a reasonable way,
3153 and don't let it get stored in any Lisp-visible variables! */
3155 static Lisp_Object
3161 {
3168 {
3171 {
3180 {
3192 else
3199 /* As a special case, we map the values `true' and `on'
3200 to Qt, and `false' and `off' to Qnil. */
3201 {
3202 Lisp_Object lower;
3210 else
3212 }
3216 }
3217 }
3218 else
3220 }
3222 }
3224 /* Record in frame F the specified or default value according to ALIST
3225 of the parameter named PROP (a Lisp symbol).
3226 If no value is specified for PROP, look for an X default for XPROP
3227 on the frame named NAME.
3228 If that is not found either, use the value DEFLT. */
3230 static Lisp_Object
3233 Lisp_Object alist;
3234 Lisp_Object prop;
3235 Lisp_Object deflt;
3239 {
3240 Lisp_Object tem;
3247 }
3248 \f
3251 Returns an alist of the form ((top . TOP), (left . LEFT) ... ).
3252 The properties returned may include `top', `left', `height', and `width'.
3253 The value of `left' or `top' may be an integer,
3254 or a list (+ N) meaning N pixels relative to top/left corner,
3257 Lisp_Object string;
3258 {
3261 Lisp_Object result;
3270 {
3271 Lisp_Object element;
3277 else
3280 }
3283 {
3284 Lisp_Object element;
3290 else
3293 }
3301 }
3303 /* Calculate the desired size and position of this window,
3304 and return the flags saying which aspects were specified.
3306 This function does not make the coordinates positive. */
3308 #define DEFAULT_ROWS 40
3309 #define DEFAULT_COLS 80
3311 static int
3314 Lisp_Object parms;
3315 {
3319 /* Default values if we fall through.
3320 Actually, if that happens we should get
3321 window manager prompting. */
3324 /* Window managers expect that if program-specified
3325 positions are not (0,0), they're intentional, not defaults. */
3329 /* Ensure that old new_width and new_height will not override the
3330 values set here. */
3338 {
3340 {
3343 }
3345 {
3348 }
3351 else
3353 }
3371 {
3373 {
3376 }
3380 {
3383 }
3387 {
3389 }
3392 else
3393 {
3398 }
3401 {
3404 }
3408 {
3411 }
3415 {
3417 }
3420 else
3421 {
3426 }
3430 else
3432 }
3435 {
3439 /* It takes both for some WM:s to place it where we want */
3448 }
3451 }
3453 \f
3457 BOOL
3459 HINSTANCE hinst;
3460 {
3461 WNDCLASS wc;
3475 }
3477 HWND
3481 {
3483 /* Position and size of scroll bar. */
3489 NULL,
3490 hinst,
3491 NULL));
3492 }
3494 void
3497 {
3498 HWND hwnd;
3499 RECT rect;
3508 /* Do first time app init */
3511 {
3513 }
3523 NULL,
3524 NULL,
3525 hinst,
3526 NULL);
3529 {
3536 /* Enable drag-n-drop. */
3539 /* Do this to discard the default setting specified by our parent. */
3541 }
3542 }
3544 void
3547 HWND hwnd;
3548 UINT msg;
3549 WPARAM wParam;
3550 LPARAM lParam;
3551 {
3559 }
3561 /* GetKeyState and MapVirtualKey on Windows 95 do not actually distinguish
3562 between left and right keys as advertised. We test for this
3563 support dynamically, and set a flag when the support is absent. If
3564 absent, we keep track of the left and right control and alt keys
3565 ourselves. This is particularly necessary on keyboards that rely
3566 upon the AltGr key, which is represented as having the left control
3567 and right alt keys pressed. For these keyboards, we need to know
3568 when the left alt key has been pressed in addition to the AltGr key
3569 so that we can properly support M-AltGr-key sequences (such as M-@
3570 on Swedish keyboards). */
3572 #define EMACS_LCONTROL 0
3573 #define EMACS_RCONTROL 1
3574 #define EMACS_LMENU 2
3575 #define EMACS_RMENU 3
3581 static void
3583 {
3589 {
3592 }
3593 else
3594 {
3597 }
3600 else
3603 }
3605 static void
3607 {
3618 else
3622 }
3624 static void
3626 {
3634 else
3638 }
3640 /* Emacs can lose focus while a modifier key has been pressed. When
3641 it regains focus, be conservative and clear all modifiers since
3642 we cannot reconstruct the left and right modifier state. */
3643 static void
3645 {
3649 /* Emacs doesn't have keyboard focus. Do nothing. */
3656 /* Clear any recorded control modifier state. */
3660 /* Clear any recorded alt modifier state. */
3663 /* Update the state of all modifier keys, because modifiers used in
3664 hot-key combinations can get stuck on if Emacs loses focus as a
3665 result of a hot-key being pressed. */
3666 {
3669 #define CURRENT_STATE(key) ((GetAsyncKeyState (key) & 0x8000) >> 8)
3683 }
3684 }
3686 /* Synchronize modifier state with what is reported with the current
3687 keystroke. Even if we cannot distinguish between left and right
3688 modifier keys, we know that, if no modifiers are set, then neither
3689 the left or right modifier should be set. */
3690 static void
3692 {
3701 }
3703 static int
3705 {
3712 {
3721 }
3723 }
3725 /* Convert between the modifier bits W32 uses and the modifier bits
3726 Emacs uses. */
3728 unsigned int
3730 {
3731 Lisp_Object key_mapping;
3734 {
3749 }
3751 /* NB. This code runs in the input thread, asychronously to the lisp
3752 thread, so we must be careful to ensure access to lisp data is
3753 thread-safe. The following code is safe because the modifier
3754 variable values are updated atomically from lisp and symbols are
3755 not relocated by GC. Also, we don't have to worry about seeing GC
3756 markbits here. */
3772 /* Don't generate any modifier if not explicitly requested. */
3774 }
3776 unsigned int
3778 {
3787 }
3789 /* We map the VK_* modifiers into console modifier constants
3790 so that we can use the same routines to handle both console
3791 and window input. */
3793 static int
3795 {
3812 }
3814 static int
3816 {
3819 /* Convert to emacs modifiers. */
3823 }
3825 unsigned int
3827 {
3844 }
3846 /* List of special key combinations which w32 would normally capture,
3847 but emacs should grab instead. Not directly visible to lisp, to
3848 simplify synchronization. Each item is an integer encoding a virtual
3849 key code and modifier combination to capture. */
3850 Lisp_Object w32_grabbed_keys;
3852 #define HOTKEY(vk,mods) make_number (((vk) & 255) | ((mods) << 8))
3853 #define HOTKEY_ID(k) (XFASTINT (k) & 0xbfff)
3854 #define HOTKEY_VK_CODE(k) (XFASTINT (k) & 255)
3855 #define HOTKEY_MODIFIERS(k) (XFASTINT (k) >> 8)
3857 /* Register hot-keys for reserved key combinations when Emacs has
3858 keyboard focus, since this is the only way Emacs can receive key
3859 combinations like Alt-Tab which are used by the system. */
3861 static void
3863 HWND hwnd;
3864 {
3865 Lisp_Object keylist;
3867 /* Use GC_CONSP, since we are called asynchronously. */
3869 {
3872 /* Deleted entries get set to nil. */
3878 }
3879 }
3881 static void
3883 HWND hwnd;
3884 {
3885 Lisp_Object keylist;
3887 /* Use GC_CONSP, since we are called asynchronously. */
3889 {
3896 }
3897 }
3899 /* Main message dispatch loop. */
3901 static void
3903 {
3904 MSG msg;
3906 HWND focus_window;
3911 {
3913 {
3915 {
3917 /* Produced by complete_deferred_msg; just ignore. */
3926 /* Reply is not expected. */
3941 /* Reply is not expected. */
3947 /* Mark item as erased. NB: this code must be
3948 thread-safe. The next line is okay because the cons
3949 cell is never made into garbage and is not relocated by
3950 GC. */
3956 {
3961 /* NB: This code must be thread-safe. It is safe to
3962 call NILP because symbols are not relocated by GC,
3963 and pointer here is not touched by GC (so the markbit
3964 can't be set). Numbers are safe because they are
3965 immediate values. */
3969 {
3982 }
3986 }
3990 }
3991 }
3992 else
3993 {
3995 }
3997 /* Exit nested loop when our deferred message has completed. */
4000 }
4001 }
4007 {
4010 /* Don't actually need synchronization for read access, since
4011 modification of single pointer is always atomic. */
4012 /* enter_crit (); */
4019 /* leave_crit (); */
4022 }
4024 static LRESULT
4026 HWND hwnd,
4027 UINT msg,
4028 WPARAM wParam,
4029 LPARAM lParam)
4030 {
4031 /* Only input thread can send deferred messages. */
4035 /* It is an error to send a message that is already deferred. */
4039 /* Enforced synchronization is not needed because this is the only
4040 function that alters deferred_msg_head, and the following critical
4041 section is guaranteed to only be serially reentered (since only the
4042 input thread can call us). */
4044 /* enter_crit (); */
4051 /* leave_crit (); */
4053 /* Start a new nested message loop to process other messages until
4054 this one is completed. */
4060 }
4062 void
4064 {
4068 /* Message may have been cancelled, so don't abort(). */
4074 /* Ensure input thread is woken so it notices the completion. */
4076 }
4078 void
4080 {
4083 /* Don't actually need synchronization for read access, since
4084 modification of single pointer is always atomic. */
4085 /* enter_crit (); */
4088 {
4091 }
4093 /* leave_crit (); */
4095 /* Ensure input thread is woken so it notices the completion. */
4097 }
4099 DWORD
4101 DWORD dw;
4102 {
4103 MSG msg;
4104 deferred_msg dummy_buf;
4106 /* Ensure our message queue is created */
4117 /* This is the inital message loop which should only exit when the
4118 application quits. */
4122 }
4124 static void
4126 HWND hwnd;
4127 UINT msg;
4128 WPARAM wParam;
4129 LPARAM lParam;
4130 DWORD modifiers;
4132 {
4133 W32Msg wmsg;
4137 /* Detect quit_char and set quit-flag directly. Note that we
4138 still need to post a message to ensure the main thread will be
4139 woken up if blocked in sys_select(), but we do NOT want to post
4140 the quit_char message itself (because it will usually be as if
4141 the user had typed quit_char twice). Instead, we post a dummy
4142 message that has no particular effect. */
4143 {
4150 {
4153 /* The choice of message is somewhat arbitrary, as long as
4154 the main thread handler just ignores it. */
4157 /* Interrupt any blocking system calls. */
4160 /* As a safety precaution, forcibly complete any deferred
4161 messages. This is a kludge, but I don't see any particularly
4162 clean way to handle the situation where a deferred message is
4163 "dropped" in the lisp thread, and will thus never be
4164 completed, eg. by the user trying to activate the menubar
4165 when the lisp thread is busy, and then typing C-g when the
4166 menubar doesn't open promptly (with the result that the
4167 menubar never responds at all because the deferred
4168 WM_INITMENU message is never completed). Another problem
4169 situation is when the lisp thread calls SendMessage (to send
4170 a window manager command) when a message has been deferred;
4171 the lisp thread gets blocked indefinitely waiting for the
4172 deferred message to be completed, which itself is waiting for
4173 the lisp thread to respond.
4175 Note that we don't want to block the input thread waiting for
4176 a reponse from the lisp thread (although that would at least
4177 solve the deadlock problem above), because we want to be able
4178 to receive C-g to interrupt the lisp thread. */
4180 }
4181 }
4184 }
4186 /* Main window procedure */
4188 LRESULT CALLBACK
4190 HWND hwnd;
4191 UINT msg;
4192 WPARAM wParam;
4193 LPARAM lParam;
4194 {
4197 W32Msg wmsg;
4201 /* Note that it is okay to call x_window_to_frame, even though we are
4202 not running in the main lisp thread, because frame deletion
4203 requires the lisp thread to synchronize with this thread. Thus, if
4204 a frame struct is returned, it can be used without concern that the
4205 lisp thread might make it disappear while we are using it.
4207 NB. Walking the frame list in this thread is safe (as long as
4208 writes of Lisp_Object slots are atomic, which they are on Windows).
4209 Although delete-frame can destructively modify the frame list while
4210 we are walking it, a garbage collection cannot occur until after
4211 delete-frame has synchronized with this thread.
4213 It is also safe to use functions that make GDI calls, such as
4214 w32_clear_rect, because these functions must obtain a DC handle
4215 from the frame struct using get_frame_dc which is thread-aware. */
4218 {
4222 {
4228 #if defined (W32_DEBUG_DISPLAY)
4230 f,
4234 }
4237 /* ignore our own changes */
4239 {
4242 /* get_frame_dc will realize our palette and force all
4243 frames to be redrawn if needed. */
4245 }
4248 {
4249 PAINTSTRUCT paintStruct;
4250 RECT update_rect;
4255 {
4258 }
4260 /* MSDN Docs say not to call BeginPaint if GetUpdateRect
4261 fails. Apparently this can happen under some
4262 circumstances. */
4264 {
4268 /* The rectangles returned by GetUpdateRect and BeginPaint
4269 do not always match. Play it safe by assuming both areas
4270 are invalid. */
4273 #if defined (W32_DEBUG_DISPLAY)
4275 f,
4281 #endif
4288 }
4290 /* If GetUpdateRect returns 0 (meaning there is no update
4291 region), assume the whole window needs to be repainted. */
4295 }
4298 /* Inform lisp thread of keyboard layout changes. */
4301 /* Clear dead keys in the keyboard state; for simplicity only
4302 preserve modifier key states. */
4303 {
4326 }
4330 /* Synchronize hot keys with normal input. */
4341 /* Ignore keystrokes we fake ourself; see below. */
4343 {
4345 /* Make sure TranslateMessage sees them though (as long as
4346 they don't produce WM_CHAR messages). This ensures that
4347 indicator lights are toggled promptly on Windows 9x, for
4348 example. */
4350 {
4353 }
4355 }
4357 /* Synchronize modifiers with current keystroke. */
4365 {
4368 {
4369 /* Prevent system from acting on keyup (which opens the
4370 Start menu if no other key was pressed) by simulating a
4371 press of Space which we will ignore. */
4373 {
4376 else
4380 }
4381 }
4387 {
4389 {
4392 else
4396 }
4397 }
4407 /* Prevent DefWindowProc from activating the menu bar if an
4408 Alt key is pressed and released by itself. */
4413 /* Decide whether to treat as modifier or function key. */
4419 /* Decide whether to treat as modifier or function key. */
4425 /* Decide whether to treat as modifier or function key. */
4430 disable_lock_key:
4431 /* Ensure the appropriate lock key state (and indicator light)
4432 remains in the same state. We do this by faking another
4433 press of the relevant key. Apparently, this really is the
4434 only way to toggle the state of the indicator lights. */
4442 /* Ensure indicator lights are updated promptly on Windows 9x
4443 (TranslateMessage apparently does this), after forwarding
4444 input event. */
4455 /* Windows maps Ctrl-Pause (aka Ctrl-Break) into VK_CANCEL,
4456 which is confusing for purposes of key binding; convert
4457 VK_CANCEL events into VK_PAUSE events. */
4461 /* Windows maps Ctrl-NumLock into VK_PAUSE, which is confusing
4462 for purposes of key binding; convert these back into
4463 VK_NUMLOCK events, at least when we want to see NumLock key
4464 presses. (Note that there is never any possibility that
4465 VK_PAUSE with Ctrl really is C-Pause as per above.) */
4470 /* If not defined as a function key, change it to a WM_CHAR message. */
4472 {
4477 {
4478 /* Always let TranslateMessage handle AltGr key chords;
4479 for some reason, ToAscii doesn't always process AltGr
4480 chords correctly. */
4482 }
4484 {
4485 /* Handle key chords including any modifiers other
4486 than shift directly, in order to preserve as much
4487 modifier information as possible. */
4489 {
4490 /* Don't translate modified alphabetic keystrokes,
4491 so the user doesn't need to constantly switch
4492 layout to type control or meta keystrokes when
4493 the normal layout translates alphabetic
4494 characters to non-ascii characters. */
4498 }
4499 else
4500 {
4501 /* Try to handle other keystrokes by determining the
4502 base character (ie. translating the base key plus
4503 shift modifier). */
4506 KEY_EVENT_RECORD key;
4516 /* 0 means an unrecognised keycode, negative means
4517 dead key. Ignore both. */
4519 {
4520 /* Forward asciified character sequence. */
4521 post_character_message
4525 }
4527 }
4528 }
4529 else
4530 {
4531 /* Let TranslateMessage handle everything else. */
4533 }
4534 }
4535 }
4537 translate:
4539 {
4545 }
4547 /* Fall through */
4555 /* Simulate middle mouse button events when left and right buttons
4556 are used together, but only if user has two button mouse. */
4562 {
4575 {
4577 {
4581 /* Generate middle mouse event instead. */
4584 }
4586 {
4587 /* Ignore button event if we've already generated a
4588 middle mouse down event. This happens if the
4589 user releases and press one of the two buttons
4590 after we've faked a middle mouse event. */
4592 }
4593 else
4594 {
4595 /* Flush out saved message. */
4597 }
4601 /* Clear message buffer. */
4603 }
4604 else
4605 {
4606 /* Hold onto message for now. */
4607 mouse_button_timer =
4616 }
4617 }
4625 {
4635 {
4636 /* Only generate event when second button is released. */
4638 {
4643 }
4644 else
4646 }
4647 else
4648 {
4649 /* Flush out saved message if necessary. */
4651 {
4653 }
4654 }
4658 /* Always clear message buffer and cancel timer. */
4665 }
4672 /* else fall through and process them. */
4675 handle_plain_button:
4676 {
4677 BOOL up;
4681 {
4688 else
4690 }
4691 }
4696 /* Need to return true for XBUTTON messages, false for others,
4697 to indicate that we processed the message. */
4701 /* If the mouse has just moved into the frame, start tracking
4702 it, so we will be notified when it leaves the frame. Mouse
4703 tracking only works under W98 and NT4 and later. On earlier
4704 versions, there is no way of telling when the mouse leaves the
4705 frame, so we just have to put up with help-echo and mouse
4706 highlighting remaining while the frame is not active. */
4708 {
4709 TRACKMOUSEEVENT tme;
4716 }
4720 {
4724 }
4726 /* Hang onto mouse move and scroll messages for a bit, to avoid
4727 sending such events to Emacs faster than it can process them.
4728 If we get more events before the timer from the first message
4729 expires, we just replace the first message. */
4732 mouse_move_timer =
4736 /* Hold onto message for now. */
4757 /* Flush out saved messages if necessary. */
4759 {
4761 {
4764 }
4767 }
4769 {
4771 {
4774 }
4777 }
4779 {
4784 {
4785 /* Free memory used by owner-drawn and help-echo strings. */
4788 }
4789 }
4793 /* Windows doesn't send us focus messages when putting up and
4794 taking down a system popup dialog as for Ctrl-Alt-Del on Windows 95.
4795 The only indication we get that something happened is receiving
4796 this message afterwards. So this is a good time to reset our
4797 keyboard modifiers' state. */
4804 /* We must ensure menu bar is fully constructed and up to date
4805 before allowing user interaction with it. To achieve this
4806 we send this message to the lisp thread and wait for a
4807 reply (whose value is not actually needed) to indicate that
4808 the menu bar is now ready for use, so we can now return.
4810 To remain responsive in the meantime, we enter a nested message
4811 loop that can process all other messages.
4813 However, we skip all this if the message results from calling
4814 TrackPopupMenu - in fact, we must NOT attempt to send the lisp
4815 thread a message because it is blocked on us at this point. We
4816 set menubar_active before calling TrackPopupMenu to indicate
4817 this (there is no possibility of confusion with real menubar
4818 being active). */
4823 /* We can receive this message even in the absence of a
4824 menubar (ie. when the system menu is activated) - in this
4825 case we do NOT want to forward the message, otherwise it
4826 will cause the menubar to suddenly appear when the user
4827 had requested it to be turned off! */
4831 {
4832 deferred_msg msg_buf;
4834 /* Detect if message has already been deferred; in this case
4835 we cannot return any sensible value to ignore this. */
4840 }
4845 /* If a menu command is not already in progress, check again
4846 after a short delay, since Windows often (always?) sends the
4847 WM_EXITMENULOOP before the corresponding WM_COMMAND message. */
4853 /* Direct handling of help_echo in menus. Should be safe now
4854 that we generate the help_echo by placing a help event in the
4855 keyboard buffer. */
4856 {
4862 }
4868 {
4872 {
4873 /* Work out dimensions for popup menu titles. */
4877 LOGFONT menu_logfont;
4878 HFONT old_font;
4879 SIZE size;
4888 {
4893 }
4894 else
4901 }
4902 }
4908 {
4912 {
4913 /* Draw popup menu title. */
4916 {
4919 LOGFONT menu_logfont;
4920 HFONT old_font;
4927 /* Always draw title as if not selected. */
4937 }
4939 }
4940 }
4943 #if 0
4944 /* Still not right - can't distinguish between clicks in the
4945 client area of the frame from clicks forwarded from the scroll
4946 bars - may have to hook WM_NCHITTEST to remember the mouse
4947 position and then check if it is in the client area ourselves. */
4949 /* Discard the mouse click that activates a frame, allowing the
4950 user to click anywhere without changing point (or worse!).
4951 Don't eat mouse clicks on scrollbars though!! */
4955 #endif
4958 /* No longer tracking mouse. */
4965 /* Inform lisp thread that a frame might have just been obscured
4966 or exposed, so should recheck visibility of all frames. */
4979 /* Relinquish the system caret. */
4981 {
4985 }
4990 {
4993 {
4996 }
4997 }
5000 command:
5011 /* Don't restrict the sizing of tip frames. */
5014 {
5015 WINDOWPLACEMENT wp;
5022 {
5023 RECT rect;
5026 DWORD font_width;
5027 DWORD line_height;
5028 DWORD internal_border;
5029 DWORD scrollbar_extra;
5030 RECT wr;
5048 /* Force width and height of client area to be exact
5049 multiples of the character cell dimensions. */
5058 {
5059 /* For right/bottom sizing we can just fix the sizes.
5060 However for top/left sizing we will need to fix the X
5061 and Y positions as well. */
5068 {
5070 {
5073 }
5074 else
5075 {
5077 }
5078 }
5081 }
5082 }
5083 }
5088 /* Hack to correct bug that allows Emacs frames to be resized
5089 below the Minimum Tracking Size. */
5091 /* Hack to allow resizing the Emacs frame above the screen size.
5092 Note that Windows 9x limits coordinates to 16-bits. */
5105 {
5106 HWND foreground_window;
5109 /* On NT 5.0, and apparently Windows 98, it is necessary to
5110 attach to the thread that currently has focus in order to
5111 pull the focus away from it. */
5122 /* Detach from the previous foreground thread. */
5128 }
5131 {
5135 }
5153 /* If there is currently no system caret, create one. */
5155 {
5156 /* Use the default caret width, and avoid changing it
5157 unneccesarily, as it confuses screen reader software. */
5160 w32_system_caret_height);
5161 }
5165 /* Ensure visible caret gets turned on when requested. */
5168 {
5171 }
5172 /* Ensure visible caret gets turned off when requested. */
5175 {
5178 }
5179 else
5183 {
5184 UINT flags;
5194 /* Remember we did a SetCapture on the initial mouse down event,
5195 so for safety, we make sure the capture is cancelled now. */
5199 /* Use menubar_active to indicate that WM_INITMENU is from
5200 TrackPopupMenu below, and should be ignored. */
5207 {
5208 MSG amsg;
5209 /* Eat any mouse messages during popupmenu */
5211 PM_REMOVE));
5212 /* Get the menu selection, if any */
5214 {
5216 }
5217 else
5218 {
5220 }
5221 }
5222 else
5223 {
5225 }
5228 }
5231 /* Check for messages registered at runtime. */
5233 {
5237 }
5239 dflt:
5241 }
5244 /* The most common default return code for handled messages is 0. */
5246 }
5248 void
5251 {
5252 MSG msg;
5257 }
5260 /* Create a tooltip window. Unlike my_create_window, we do not do this
5261 indirectly via the Window thread, as we do not need to process Window
5262 messages for the tooltip. Creating tooltips indirectly also creates
5263 deadlocks when tooltips are created for menu items. */
5264 void
5267 {
5268 RECT rect;
5286 NULL,
5287 hinst,
5288 NULL);
5291 {
5297 /* Tip frames have no scrollbars. */
5300 /* Do this to discard the default setting specified by our parent. */
5302 }
5303 }
5306 /* Create and set up the w32 window for frame F. */
5308 static void
5313 {
5314 BLOCK_INPUT;
5316 /* Use the resource name as the top-level window name
5317 for looking up resources. Make a non-Lisp copy
5318 for the window manager, so GC relocation won't bother it.
5320 Elsewhere we specify the window name for the window manager. */
5322 {
5326 }
5332 /* x_set_name normally ignores requests to set the name if the
5333 requested name is the same as the current name. This is the one
5334 place where that assumption isn't correct; f->name is set, but
5335 the server hasn't been told. */
5336 {
5337 Lisp_Object name;
5344 }
5346 UNBLOCK_INPUT;
5353 }
5355 /* Handle the icon stuff for this window. Perhaps later we might
5356 want an x_set_icon_position which can be called interactively as
5357 well. */
5359 static void
5362 Lisp_Object parms;
5363 {
5366 /* Set the position of the icon. Note that Windows 95 groups all
5367 icons in the tray. */
5371 {
5374 }
5378 BLOCK_INPUT;
5384 /* Start up iconic or window? */
5385 x_wm_set_window_state
5387 ? IconicState
5393 #endif
5395 UNBLOCK_INPUT;
5396 }
5399 static void
5402 {
5403 XGCValues gc_values;
5405 BLOCK_INPUT;
5407 /* Create the GC's of this frame.
5408 Note that many default values are used. */
5410 /* Normal video */
5413 /* Cursor has cursor-color background, background-color foreground. */
5421 /* Reliefs. */
5425 UNBLOCK_INPUT;
5426 }
5429 /* Handler for signals raised during x_create_frame and
5430 x_create_top_frame. FRAME is the frame which is partially
5431 constructed. */
5433 static Lisp_Object
5435 Lisp_Object frame;
5436 {
5439 /* If frame is ``official'', nothing to do. */
5441 {
5442 #ifdef GLYPH_DEBUG
5444 #endif
5448 /* Check that reference counts are indeed correct. */
5453 }
5456 }
5462 Returns an Emacs frame object.
5463 ALIST is an alist of frame parameters.
5464 If the parameters specify that the frame should not have a minibuffer,
5465 and do not specify a specific minibuffer window to use,
5466 then `default-minibuffer-frame' must be a frame whose minibuffer can
5467 be shared by the new frame.
5471 Lisp_Object parms;
5472 {
5475 Lisp_Object name;
5481 Lisp_Object display;
5483 Lisp_Object parent;
5488 /* Use this general default value to start with
5489 until we know if this frame has a specified name. */
5496 #ifdef MULTI_KBOARD
5498 #else
5500 #endif
5511 /* See if parent window is specified. */
5518 /* make_frame_without_minibuffer can run Lisp code and garbage collect. */
5519 /* No need to protect DISPLAY because that's not used after passing
5520 it to make_frame_without_minibuffer. */
5524 RES_TYPE_SYMBOL);
5528 {
5531 }
5534 else
5539 /* Note that Windows does support scroll bars. */
5541 /* By default, make scrollbars the system standard width. */
5551 f->icon_name
5556 /* FRAME_W32_DISPLAY_INFO (f) = dpyinfo; */
5557 #ifdef MULTI_KBOARD
5559 #endif
5561 /* Specify the parent under which to make this window. */
5564 {
5567 }
5568 else
5569 {
5572 }
5574 /* Set the name; the functions to which we pass f expect the name to
5575 be set. */
5577 {
5580 }
5581 else
5582 {
5585 /* use the frame's title when getting resources for this frame. */
5587 }
5589 /* Extract the window parameters from the supplied values
5590 that are needed to determine window geometry. */
5591 {
5592 Lisp_Object font;
5596 BLOCK_INPUT;
5597 /* First, try whatever font the caller has specified. */
5599 {
5603 else
5605 }
5606 /* Try out a font which we hope has bold and italic variations. */
5611 /* If those didn't work, look for something which will at least work. */
5614 UNBLOCK_INPUT;
5620 }
5624 /* This defaults to 2 in order to match xterm. We recognize either
5625 internalBorderWidth or internalBorder (which is what xterm calls
5626 it). */
5628 {
5629 Lisp_Object value;
5635 parms);
5636 }
5637 /* Default internalBorderWidth to 0 on Windows to match other programs. */
5643 /* Also do the stuff which must be set before the window exists. */
5664 /* Init faces before x_default_parameter is called for scroll-bar
5665 parameters because that function calls x_set_scroll_bar_width,
5666 which calls change_frame_size, which calls Fset_window_buffer,
5667 which runs hooks, which call Fvertical_motion. At the end, we
5668 end up in init_iterator with a null face cache, which should not
5669 happen. */
5686 /* Add the tool-bar height to the initial frame height so that the
5687 user gets a text display area of the size he specified with -g or
5688 via .Xdefaults. Later changes of the tool-bar height don't
5689 change the frame size. This is done so that users can create
5690 tall Emacs frames without having to guess how tall the tool-bar
5691 will get. */
5693 {
5697 ? tool_bar_button_relief
5707 else
5712 }
5717 {
5720 else
5722 }
5723 else
5724 {
5727 else
5729 }
5741 /* Now consider the frame official. */
5745 /* We need to do this after creating the window, so that the
5746 icon-creation functions can say whose icon they're describing. */
5759 /* Dimensions, especially f->height, must be done via change_frame_size.
5760 Change will not be effected unless different from the current
5761 f->height. */
5769 /* Tell the server what size and position, etc, we want, and how
5770 badly we want them. This should be done after we have the menu
5771 bar so that its size can be taken into account. */
5772 BLOCK_INPUT;
5774 UNBLOCK_INPUT;
5776 /* Avoid a bug that causes the new frame to never become visible if
5777 an echo area message is displayed during the following call1. */
5780 /* Set up faces after all frame parameters are known. This call
5781 also merges in face attributes specified for new frames. If we
5782 don't do this, the `menu' face for instance won't have the right
5783 colors, and the menu bar won't appear in the specified colors for
5784 new frames. */
5787 /* Make the window appear on the frame and enable display, unless
5788 the caller says not to. However, with explicit parent, Emacs
5789 cannot control visibility, so don't try. */
5791 {
5792 Lisp_Object visibility;
5802 else
5803 /* Must have been Qnil. */
5804 ;
5805 }
5806 UNGCPRO;
5808 /* Make sure windows on this frame appear in calls to next-window
5809 and similar functions. */
5813 }
5815 /* FRAME is used only to get a handle on the X display. We don't pass the
5816 display info directly because we're called from frame.c, which doesn't
5817 know about that structure. */
5818 Lisp_Object
5821 {
5823 Lisp_Object xfocus;
5829 }
5834 Lisp_Object frame;
5835 {
5838 }
5840 \f
5841 /* Return the charset portion of a font name. */
5843 {
5858 }
5872 {
5874 Lisp_Object font_names;
5876 /* Get a list of all the fonts that match this name. Once we
5877 have a list of matching fonts, we compare them against the fonts
5878 we already have loaded by comparing names. */
5882 {
5883 Lisp_Object tail;
5886 /* First check if any are already loaded, as that is cheaper
5887 than loading another one. */
5898 }
5900 {
5901 /* If EnumFontFamiliesEx was available, we got a full list of
5902 fonts back so stop now to avoid the possibility of loading a
5903 random font. If we had to fall back to EnumFontFamilies, the
5904 list is incomplete, so continue whether the font we want was
5905 listed or not. */
5907 FARPROC enum_font_families_ex
5911 }
5913 /* Load the font and add it to the table. */
5914 {
5918 LOGFONT lf;
5919 BOOL ok;
5927 /* If no name was specified for the font, we get a random font
5928 from CreateFontIndirect - this is not particularly
5929 desirable, especially since CreateFontIndirect does not
5930 fill out the missing name in lf, so we never know what we
5931 ended up with. */
5934 /* Specify anti-aliasing to prevent Cleartype fonts being used,
5935 since those fonts leave garbage behind. */
5941 /* Set bdf to NULL to indicate that this is a Windows font. */
5944 BLOCK_INPUT;
5949 {
5951 }
5952 else
5953 {
5954 HDC hdc;
5955 HANDLE oldobj;
5965 else
5966 {
5967 /* Unfortunately, some fonts (eg. MingLiU, a big5 ttf font)
5968 don't report themselves as double byte fonts, when
5969 patently they are. So instead of trusting
5970 GetFontLanguageInfo, we check the properties of the
5971 codepage directly, since that is ultimately what we are
5972 working from anyway. */
5973 /* font->double_byte_p = GetFontLanguageInfo(hdc) & GCP_DBCS; */
5977 }
5981 /* Fill out details in lf according to the font that was
5982 actually loaded. */
5994 }
5996 UNBLOCK_INPUT;
5999 {
6002 }
6004 /* Find a free slot in the font table. */
6009 /* If no free slot found, maybe enlarge the font table. */
6012 {
6016 dpyinfo->font_table
6018 }
6024 /* Now fill in the slots of *FONTP. */
6025 BLOCK_INPUT;
6033 /* Cache the W32 codepage for a font. This makes w32_encode_char
6034 (called for every glyph during redisplay) much faster. */
6037 /* Work out the font's full name. */
6041 else
6042 {
6043 /* If all else fails - just use the name we used to load it. */
6046 }
6051 /* The slot `encoding' specifies how to map a character
6052 code-points (0x20..0x7F or 0x2020..0x7F7F) of each charset to
6053 the font code-points (0:0x20..0x7F, 1:0xA0..0xFF), or
6054 (0:0x20..0x7F, 1:0xA0..0xFF,
6055 (0:0x2020..0x7F7F, 1:0xA0A0..0xFFFF, 3:0x20A0..0x7FFF,
6056 2:0xA020..0xFF7F). For the moment, we don't know which charset
6057 uses this font. So, we set information in fontp->encoding[1]
6058 which is never used by any charset. If mapping can't be
6059 decided, set FONT_ENCODING_NOT_DECIDED. */
6061 /* SJIS fonts need to be set to type 4, all others seem to work as
6062 type FONT_ENCODING_NOT_DECIDED. */
6066 else
6069 /* The following three values are set to 0 under W32, which is
6070 what they get set to if XGetFontProperty fails under X. */
6075 /* Set global flag fonts_changed_p to non-zero if the font loaded
6076 has a character with a smaller width than any other character
6077 before, or if the font loaded has a smaller height than any
6078 other font loaded before. If this happens, it will make a
6079 glyph matrix reallocation necessary. */
6081 UNBLOCK_INPUT;
6083 }
6084 }
6086 /* Load font named FONTNAME of size SIZE for frame F, and return a
6087 pointer to the structure font_info while allocating it dynamically.
6088 If loading fails, return NULL. */
6094 {
6095 Lisp_Object bdf_fonts;
6101 {
6103 Lisp_Object bdf_pair;
6112 }
6118 }
6121 void
6125 {
6127 {
6133 }
6134 }
6136 /* The font conversion stuff between x and w32 */
6138 /* X font string is as follows (from faces.el)
6139 * (let ((- "[-?]")
6140 * (foundry "[^-]+")
6141 * (family "[^-]+")
6142 * (weight "\\(bold\\|demibold\\|medium\\)") ; 1
6143 * (weight\? "\\([^-]*\\)") ; 1
6144 * (slant "\\([ior]\\)") ; 2
6145 * (slant\? "\\([^-]?\\)") ; 2
6146 * (swidth "\\([^-]*\\)") ; 3
6147 * (adstyle "[^-]*") ; 4
6148 * (pixelsize "[0-9]+")
6149 * (pointsize "[0-9][0-9]+")
6150 * (resx "[0-9][0-9]+")
6151 * (resy "[0-9][0-9]+")
6152 * (spacing "[cmp?*]")
6153 * (avgwidth "[0-9]+")
6154 * (registry "[^-]+")
6155 * (encoding "[^-]+")
6156 * )
6157 */
6159 static LONG
6162 {
6175 else
6177 }
6183 {
6193 else
6195 }
6197 static LONG
6200 {
6205 /* Support "*-#nnn" format for unknown charsets. */
6209 /* Handle wildcards by ignoring them; eg. treat "big5*-*" as "big5". */
6216 /* Look through w32-charset-info-alist for the character set.
6217 Format of each entry is
6218 (CHARSET_NAME . (WINDOWS_CHARSET . CODEPAGE)).
6219 */
6223 {
6224 /* At startup, we want iso8859-1 fonts to come up properly. */
6227 else
6229 }
6233 /* Translate Lisp symbol to number. */
6248 #ifdef JOHAB_CHARSET
6272 #ifdef UNICODE_CHARSET
6275 #endif
6278 }
6284 {
6286 Lisp_Object charset_type;
6289 {
6291 /* Handle startup case of w32-charset-info-alist not
6292 being set up yet. */
6319 /* More recent versions of Windows (95 and NT4.0) define more
6320 character sets. */
6321 #ifdef EASTEUROPE_CHARSET
6355 #endif
6357 #ifdef UNICODE_CHARSET
6361 #endif
6363 /* Encode numerical value of unknown charset. */
6366 }
6368 {
6369 Lisp_Object rest;
6372 /* Look through w32-charset-info-alist for the character set.
6373 Prefer ISO codepages, and prefer lower numbers in the ISO
6374 range. Only return charsets for codepages which are installed.
6376 Format of each entry is
6377 (CHARSET_NAME . (WINDOWS_CHARSET . CODEPAGE)).
6378 */
6380 {
6382 Lisp_Object w32_charset;
6383 Lisp_Object codepage;
6387 /* Skip invalid entries in alist. */
6397 /* Look for Same charset and a valid codepage (or non-int
6398 which means ignore). */
6402 {
6403 /* If we don't have a match already, then this is the
6404 best. */
6407 /* If this is an ISO codepage, and the best so far isn't,
6408 then this is better. */
6412 /* If both are ISO8859 codepages, choose the one with the
6413 lowest number in the encoding field. */
6416 {
6421 }
6422 }
6423 }
6425 /* If no match, encode the numeric value. */
6427 {
6430 }
6435 }
6436 }
6439 /* Return all the X charsets that map to a font. */
6440 static Lisp_Object
6443 {
6445 Lisp_Object charset_type;
6449 {
6451 /* Handle startup case of w32-charset-info-alist not
6452 being set up yet. */
6479 /* More recent versions of Windows (95 and NT4.0) define more
6480 character sets. */
6481 #ifdef EASTEUROPE_CHARSET
6515 #endif
6517 #ifdef UNICODE_CHARSET
6521 #endif
6523 /* Encode numerical value of unknown charset. */
6526 }
6528 {
6529 Lisp_Object rest;
6530 /* Look through w32-charset-info-alist for the character set.
6531 Only return charsets for codepages which are installed.
6533 Format of each entry in Vw32_charset_info_alist is
6534 (CHARSET_NAME . (WINDOWS_CHARSET . CODEPAGE)).
6535 */
6537 {
6538 Lisp_Object x_charset;
6539 Lisp_Object w32_charset;
6540 Lisp_Object codepage;
6544 /* Skip invalid entries in alist. */
6554 /* Look for Same charset and a valid codepage (or non-int
6555 which means ignore). */
6559 {
6561 }
6562 }
6564 /* If no match, encode the numeric value. */
6566 {
6569 }
6572 }
6573 }
6575 /* Get the Windows codepage corresponding to the specified font. The
6576 charset info in the font name is used to look up
6577 w32-charset-to-codepage-alist. */
6578 int
6580 {
6587 /* Extract charset part of font string. */
6596 #if 0
6597 /* Remove leading "*-". */
6600 else
6601 #endif
6604 /* Stop match at wildcard (including preceding '-'). */
6606 {
6608 end--;
6610 }
6624 else
6626 }
6629 static BOOL
6635 {
6656 else
6671 /* Replace dashes with underscores so the dashes are not
6672 misinterpreted. */
6678 {
6682 }
6683 else
6684 {
6687 }
6690 else
6699 /* setwidth name */
6700 /* add style name */
6708 specific_charset ? specific_charset
6710 /* charset registry and encoding */
6711 );
6715 }
6717 static BOOL
6721 {
6728 /* Set default value for each field. */
6729 #if 1
6733 #else
6734 /* go for maximum quality */
6738 #endif
6747 /* Provide a simple escape mechanism for specifying Windows font names
6748 * directly -- if font spec does not beginning with '-', assume this
6749 * format:
6750 * "<font name>[:height in pixels[:width in pixels[:weight]]]"
6751 */
6754 {
6767 /* In the general case when wildcards cover more than one field,
6768 we don't know which field is which, so don't fill any in.
6769 However, we need to cope with this particular form, which is
6770 generated by font_list_1 (invoked by try_font_list):
6771 "-raster-6x10-*-gb2312*-*"
6772 and make sure to correctly parse the charset field. */
6774 {
6778 }
6780 {
6783 }
6786 {
6790 setup_coding_system
6802 }
6803 else
6804 {
6806 }
6808 fields--;
6812 fields--;
6816 fields--;
6821 fields--;
6822 fields--;
6824 {
6827 }
6836 fields--;
6841 fields--;
6843 /* Strip the trailing '-' if present. (it shouldn't be, as it
6844 fails the test against xlfd-tight-regexp in fontset.el). */
6845 {
6849 }
6851 #if 0
6854 #endif
6856 }
6857 else
6858 {
6869 {
6872 }
6873 else
6874 {
6876 }
6878 fields--;
6883 fields--;
6888 fields--;
6891 }
6893 /* This makes TrueType fonts work better. */
6897 }
6899 /* Strip the pixel height and point height from the given xlfd, and
6900 return the pixel height. If no pixel height is specified, calculate
6901 one from the point height, or if that isn't defined either, return
6902 0 (which usually signifies a scalable font).
6903 */
6904 static int
6906 {
6915 /* Look for height fields. */
6917 {
6919 {
6920 field_number++;
6922 {
6923 read_from++;
6926 /* Find end of field. */
6928 ;
6930 /* Split the fontname at end of field. */
6932 {
6934 read_from++;
6935 }
6937 /* Blank out field. */
6939 {
6941 write_to++;
6942 }
6943 /* If the pixel height field is at the end (partial xlfd),
6944 return now. */
6945 else
6948 /* If we got a pixel height, the point height can be
6949 ignored. Just blank it out and break now. */
6951 {
6952 /* Find end of point size field. */
6954 ;
6957 read_from++;
6959 /* Blank out the point size field. */
6961 {
6963 write_to++;
6964 }
6965 else
6969 }
6970 /* If the point height is already blank, break now. */
6972 {
6973 read_from++;
6975 }
6976 }
6978 {
6979 /* If we didn't get a pixel height, try to get the point
6980 height and convert that. */
6984 /* Find end of field. */
6986 ;
6989 {
6991 read_from++;
6992 }
6996 /* Convert to pixel height. */
6997 pixel_height = point_size
7000 /* Blank out this field and break. */
7002 write_to++;
7004 }
7005 }
7006 }
7008 /* Shift the rest of the font spec into place. */
7010 {
7014 }
7017 }
7019 /* Assume parameter 1 is fully qualified, no wildcards. */
7020 static BOOL
7024 {
7029 /* Copy fontname so we can modify it during comparison. */
7035 /* Turn pattern into a regexp and do a regexp match. */
7037 {
7041 {
7044 }
7045 else
7047 }
7051 /* Strip out font heights and compare them seperately, since
7052 rounding error can cause mismatches. This also allows a
7053 comparison between a font that declares only a pixel height and a
7054 pattern that declares the point height.
7055 */
7056 {
7062 /* Compare now, and don't bother doing expensive regexp matching
7063 if the heights differ. */
7066 }
7070 }
7072 /* Callback functions, and a structure holding info they need, for
7073 listing system fonts on W32. We need one set of functions to do the
7074 job properly, but these don't work on NT 3.51 and earlier, so we
7075 have a second set which don't handle character sets properly to
7076 fall back on.
7078 In both cases, there are two passes made. The first pass gets one
7079 font from each family, the second pass lists all the fonts from
7080 each family. */
7083 {
7084 HDC hdc;
7086 LOGFONT logfont;
7089 Lisp_Object list;
7094 static void
7098 static int CALLBACK
7104 {
7105 /* Ignore struck out and underlined versions of fonts. */
7109 /* Only return fonts with names starting with @ if they were
7110 explicitly specified, since Microsoft uses an initial @ to
7111 denote fonts for vertical writing, without providing a more
7112 convenient way of identifying them. */
7117 /* Check that the character set matches if it was specified */
7122 {
7128 /* Truetype fonts do not report their true metrics until loaded */
7130 {
7132 {
7133 /* Scalable fonts are as big as you want them to be. */
7137 }
7138 else
7139 {
7142 }
7143 }
7145 /* Make sure the height used here is the same as everywhere
7146 else (ie character height, not cell height). */
7148 {
7149 /* lptm can be trusted for RASTER fonts, but not scalable ones. */
7152 else
7154 }
7157 {
7160 /* We already checked charsets above, but DEFAULT_CHARSET
7161 slipped through. So only allow exact matches for DEFAULT_CHARSET. */
7167 }
7171 else
7174 /* Loop through the charsets. */
7176 {
7180 /* List bold and italic variations if w32-enable-synthesized-fonts
7181 is non-nil and this is a plain font. */
7185 {
7188 /* bold. */
7192 /* bold italic. */
7196 /* italic. */
7200 }
7201 else
7204 }
7205 }
7208 }
7210 static void
7215 Lisp_Object width;
7216 {
7224 {
7225 /* Check if we already listed this font. This may happen if
7226 w32_enable_synthesized_fonts is non-nil, and there are real
7227 bold and italic versions of the font. */
7230 {
7234 }
7235 }
7236 }
7239 static int CALLBACK
7245 {
7250 }
7253 static int CALLBACK
7259 {
7260 /* We are not interested in the extra info we get back from the 'Ex
7261 version - only the fact that we get character set variations
7262 enumerated seperately. */
7265 }
7267 static int CALLBACK
7273 {
7275 FARPROC enum_font_families_ex
7277 /* We don't really expect EnumFontFamiliesEx to disappear once we
7278 get here, so don't bother handling it gracefully. */
7285 }
7287 /* Interface to fontset handler. (adapted from mw32font.c in Meadow
7288 and xterm.c in Emacs 20.3) */
7291 {
7300 {
7306 else
7310 {
7312 n_fonts++;
7315 }
7316 }
7319 }
7322 /* Return a list of names of available fonts matching PATTERN on frame
7323 F. If SIZE is not 0, it is the size (maximum bound width) of fonts
7324 to be listed. Frame F NULL means we have not yet created any
7325 frame, which means we can't get proper size info, as we don't have
7326 a device context to use for GetTextMetrics.
7327 MAXNAMES sets a limit on how many fonts to match. */
7329 Lisp_Object
7332 Lisp_Object pattern;
7335 {
7346 {
7347 enumfont_t ef;
7355 /* Avoid expensive EnumFontFamilies functions if we are not
7356 going to be able to output one of these anyway. */
7363 /* See if we cached the result for this particular query.
7364 The cache is an alist of the form:
7365 ((PATTERN (FONTNAME . WIDTH) ...) ...)
7366 */
7369 {
7371 /* We have a cached list. Don't have to get the list again. */
7373 }
7375 BLOCK_INPUT;
7376 /* At first, put PATTERN in the cache. */
7383 /* Use EnumFontFamiliesEx where it is available, as it knows
7384 about character sets. Fall back to EnumFontFamilies for
7385 older versions of NT that don't support the 'Ex function. */
7387 {
7388 LOGFONT font_match_pattern;
7390 FARPROC enum_font_families_ex
7393 /* We do our own pattern matching so we can handle wildcards. */
7396 /* We can use the charset, because if it is a wildcard it will
7397 be DEFAULT_CHARSET anyway. */
7407 else
7412 }
7414 UNBLOCK_INPUT;
7416 /* Make a list of the fonts we got back.
7417 Store that in the font cache for the display. */
7422 label_cached:
7427 /* Make a list of the fonts that have the right width. */
7429 {
7438 {
7440 n_fonts++;
7443 else
7445 }
7447 {
7448 /* Since we don't yet know the size of the font, we must
7449 load it and try GetTextMetrics. */
7450 W32FontStruct thisinfo;
7451 LOGFONT lf;
7452 HDC hdc;
7453 HANDLE oldobj;
7458 BLOCK_INPUT;
7468 else
7473 UNBLOCK_INPUT;
7474 }
7477 {
7479 n_fonts++;
7482 }
7483 /* keep track of the closest matching size in case
7484 no exact match is found. */
7486 {
7491 {
7495 }
7496 else
7497 {
7500 found_size)
7502 }
7503 }
7504 }
7509 {
7512 }
7513 }
7515 /* Include any bdf fonts. */
7517 {
7522 }
7525 }
7528 /* Return a pointer to struct font_info of font FONT_IDX of frame F. */
7531 FRAME_PTR f;
7533 {
7535 }
7540 {
7547 {
7549 }
7552 }
7554 /* Find a CCL program for a font specified by FONTP, and set the member
7555 `encoder' of the structure. */
7557 void
7560 {
7564 {
7571 }
7573 {
7579 else
7581 }
7582 }
7584 \f
7585 /* Find BDF files in a specified directory. (use GCPRO when calling,
7586 as this calls lisp to get a directory listing). */
7587 static Lisp_Object
7589 {
7600 {
7604 }
7606 }
7611 The list is suitable for appending to w32-bdf-filename-alist. Fonts
7612 which do not contain an xlfd description will not be included in the
7615 Lisp_Object directory;
7616 {
7624 {
7631 UNGCPRO;
7632 }
7634 }
7636 \f
7641 {
7642 XColor foo;
7649 else
7651 }
7657 {
7658 XColor foo;
7664 {
7674 }
7675 else
7677 }
7682 Lisp_Object display;
7683 {
7690 }
7695 Note that color displays do support shades of gray.
7696 The optional argument DISPLAY specifies which display to ask about.
7697 DISPLAY should be either a frame or a display name (a string).
7700 Lisp_Object display;
7701 {
7708 }
7713 The optional argument DISPLAY specifies which display to ask about.
7714 DISPLAY should be either a frame or a display name (a string).
7717 Lisp_Object display;
7718 {
7722 }
7727 The optional argument DISPLAY specifies which display to ask about.
7728 DISPLAY should be either a frame or a display name (a string).
7731 Lisp_Object display;
7732 {
7736 }
7741 The optional argument DISPLAY specifies which display to ask about.
7742 DISPLAY should be either a frame or a display name (a string).
7745 Lisp_Object display;
7746 {
7750 }
7755 The optional argument DISPLAY specifies which display to ask about.
7756 DISPLAY should be either a frame or a display name (a string).
7759 Lisp_Object display;
7760 {
7762 HDC hdc;
7768 else
7777 }
7780 Sx_server_max_request_size,
7783 The optional argument DISPLAY specifies which display to ask about.
7784 DISPLAY should be either a frame or a display name (a string).
7787 Lisp_Object display;
7788 {
7792 }
7796 The optional argument DISPLAY specifies which display to ask about.
7797 DISPLAY should be either a frame or a display name (a string).
7800 Lisp_Object display;
7801 {
7803 }
7807 The value is a list of three integers: the major and minor
7808 version numbers, and the vendor-specific release
7809 number. See also the function `x-server-vendor'.
7811 The optional argument DISPLAY specifies which display to ask about.
7812 DISPLAY should be either a frame or a display name (a string).
7815 Lisp_Object display;
7816 {
7820 }
7824 The optional argument DISPLAY specifies which display to ask about.
7825 DISPLAY should be either a frame or a display name (a string).
7828 Lisp_Object display;
7829 {
7831 }
7836 The optional argument DISPLAY specifies which display to ask about.
7837 DISPLAY should be either a frame or a display name (a string).
7840 Lisp_Object display;
7841 {
7843 HDC hdc;
7853 }
7857 The optional argument DISPLAY specifies which display to ask about.
7858 DISPLAY should be either a frame or a display name (a string).
7861 Lisp_Object display;
7862 {
7865 HDC hdc;
7875 }
7880 The value may be `always', `when-mapped', or `not-useful'.
7881 The optional argument DISPLAY specifies which display to ask about.
7882 DISPLAY should be either a frame or a display name (a string).
7885 Lisp_Object display;
7886 {
7888 }
7893 The value is one of the symbols `static-gray', `gray-scale',
7894 `static-color', `pseudo-color', `true-color', or `direct-color'.
7896 The optional argument DISPLAY specifies which display to ask about.
7897 DISPLAY should be either a frame or a display name (a string).
7900 Lisp_Object display;
7901 {
7915 }
7920 The optional argument DISPLAY specifies which display to ask about.
7921 DISPLAY should be either a frame or a display name (a string).
7924 Lisp_Object display;
7925 {
7927 }
7928 \f
7929 int
7932 {
7934 }
7936 int
7939 {
7941 }
7943 int
7946 {
7948 }
7950 int
7953 {
7955 }
7957 int
7960 {
7962 }
7963 \f
7964 /* Return the display structure for the display named NAME.
7965 Open a new connection if necessary. */
7969 Lisp_Object name;
7970 {
7971 Lisp_Object names;
7977 dpyinfo;
7979 {
7980 Lisp_Object tem;
7984 }
7986 /* Use this general default value to start with. */
8001 }
8005 DISPLAY is the name of the display to connect to.
8006 Optional second arg XRM-STRING is a string of resources in xrdb format.
8007 If the optional third arg MUST-SUCCEED is non-nil,
8011 {
8015 /* If initialization has already been done, return now to avoid
8016 overwriting critical parts of one_w32_display_info. */
8027 /* Allow color mapping to be defined externally; first look in user's
8028 HOME directory, then in Emacs etc dir for a file called rgb.txt. */
8029 {
8030 Lisp_Object color_file;
8038 color_file =
8044 UNGCPRO;
8045 }
8051 else
8054 /* Use this general default value to start with. */
8055 /* First remove .exe suffix from invocation-name - it looks ugly. */
8056 {
8063 }
8068 /* This is what opens the connection and sets x_current_display.
8069 This also initializes many symbols, such as those used for input. */
8074 {
8078 else
8080 }
8086 }
8091 For DISPLAY, specify either a frame or a display name (a string).
8094 Lisp_Object display;
8095 {
8102 BLOCK_INPUT;
8103 /* Free the fonts in the font table. */
8106 {
8111 }
8115 UNBLOCK_INPUT;
8118 }
8122 ()
8123 {
8131 }
8137 {
8139 }
8141 \f
8142 \f
8143 /***********************************************************************
8144 Image types
8145 ***********************************************************************/
8147 /* Value is the number of elements of vector VECTOR. */
8149 #define DIM(VECTOR) (sizeof (VECTOR) / sizeof *(VECTOR))
8151 /* List of supported image types. Use define_image_type to add new
8152 types. Use lookup_image_type to find a type for a given symbol. */
8156 /* The symbol `image' which is the car of the lists used to represent
8157 images in Lisp. */
8161 /* The symbol `xbm' which is used as the type symbol for XBM images. */
8163 Lisp_Object Qxbm;
8165 /* Keywords. */
8173 /* Other symbols. */
8177 /* Time in seconds after which images should be removed from the cache
8178 if not displayed. */
8180 Lisp_Object Vimage_cache_eviction_delay;
8182 /* Function prototypes. */
8190 Lisp_Object));
8193 /* Define a new image type from TYPE. This adds a copy of TYPE to
8194 image_types and adds the symbol *TYPE->type to Vimage_types. */
8196 static void
8199 {
8200 /* Make a copy of TYPE to avoid a bus error in a dumped Emacs.
8201 The initialized data segment is read-only. */
8207 }
8210 /* Look up image type SYMBOL, and return a pointer to its image_type
8211 structure. Value is null if SYMBOL is not a known image type. */
8215 Lisp_Object symbol;
8216 {
8224 }
8227 /* Value is non-zero if OBJECT is a valid Lisp image specification. A
8228 valid image specification is a list whose car is the symbol
8229 `image', and whose rest is a property list. The property list must
8230 contain a value for key `:type'. That value must be the name of a
8231 supported image type. The rest of the property list depends on the
8232 image type. */
8234 int
8236 Lisp_Object object;
8237 {
8241 {
8242 Lisp_Object tem;
8246 {
8249 {
8254 }
8257 }
8258 }
8261 }
8264 /* Log error message with format string FORMAT and argument ARG.
8265 Signaling an error, e.g. when an image cannot be loaded, is not a
8266 good idea because this would interrupt redisplay, and the error
8267 message display would lead to another redisplay. This function
8268 therefore simply displays a message. */
8270 static void
8274 {
8276 }
8279 \f
8280 /***********************************************************************
8281 Image specifications
8282 ***********************************************************************/
8284 enum image_value_type
8285 {
8286 IMAGE_DONT_CHECK_VALUE_TYPE,
8287 IMAGE_STRING_VALUE,
8288 IMAGE_STRING_OR_NIL_VALUE,
8289 IMAGE_SYMBOL_VALUE,
8290 IMAGE_POSITIVE_INTEGER_VALUE,
8291 IMAGE_POSITIVE_INTEGER_VALUE_OR_PAIR,
8292 IMAGE_NON_NEGATIVE_INTEGER_VALUE,
8293 IMAGE_ASCENT_VALUE,
8294 IMAGE_INTEGER_VALUE,
8295 IMAGE_FUNCTION_VALUE,
8296 IMAGE_NUMBER_VALUE,
8297 IMAGE_BOOL_VALUE
8298 };
8300 /* Structure used when parsing image specifications. */
8302 struct image_keyword
8303 {
8304 /* Name of keyword. */
8307 /* The type of value allowed. */
8310 /* Non-zero means key must be present. */
8313 /* Used to recognize duplicate keywords in a property list. */
8316 /* The value that was found. */
8317 Lisp_Object value;
8318 };
8326 /* Parse image spec SPEC according to KEYWORDS. A valid image spec
8327 has the format (image KEYWORD VALUE ...). One of the keyword/
8328 value pairs must be `:type TYPE'. KEYWORDS is a vector of
8329 image_keywords structures of size NKEYWORDS describing other
8330 allowed keyword/value pairs. Value is non-zero if SPEC is valid. */
8332 static int
8334 Lisp_Object spec;
8337 Lisp_Object type;
8338 {
8340 Lisp_Object plist;
8347 {
8350 /* First element of a pair must be a symbol. */
8356 /* There must follow a value. */
8362 /* Find key in KEYWORDS. Error if not found. */
8370 /* Record that we recognized the keyword. If a keywords
8371 was found more than once, it's an error. */
8378 /* Check type of value against allowed type. */
8380 {
8453 }
8457 }
8459 /* Check that all mandatory fields are present. */
8465 }
8468 /* Return the value of KEY in image specification SPEC. Value is nil
8469 if KEY is not present in SPEC. if FOUND is not null, set *FOUND
8470 to 1 if KEY was found in SPEC, set it to 0 otherwise. */
8472 static Lisp_Object
8476 {
8477 Lisp_Object tail;
8484 {
8486 {
8490 }
8491 }
8496 }
8500 \f
8501 /***********************************************************************
8502 Image type independent image structures
8503 ***********************************************************************/
8509 /* Allocate and return a new image structure for image specification
8510 SPEC. SPEC has a hash value of HASH. */
8514 Lisp_Object spec;
8516 {
8528 }
8531 /* Free image IMG which was used on frame F, including its resources. */
8533 static void
8537 {
8539 {
8542 /* Remove IMG from the hash table of its cache. */
8545 else
8553 /* Free resources, then free IMG. */
8556 }
8557 }
8560 /* Prepare image IMG for display on frame F. Must be called before
8561 drawing an image. */
8563 void
8567 {
8568 EMACS_TIME t;
8570 /* We're about to display IMG, so set its timestamp to `now'. */
8574 /* If IMG doesn't have a pixmap yet, load it now, using the image
8575 type dependent loader function. */
8578 }
8581 /* Value is the number of pixels for the ascent of image IMG when
8582 drawn in face FACE. */
8584 int
8588 {
8593 {
8597 else
8599 }
8600 else
8604 }
8607 \f
8608 /* Image background colors. */
8610 static unsigned long
8614 {
8619 /* Get the colors at the corners of ximg. */
8625 /* Choose the most frequently found color as background. */
8627 {
8636 }
8639 #else
8641 #endif
8642 }
8644 /* Return the `background' field of IMG. If IMG doesn't have one yet,
8645 it is guessed heuristically. If non-zero, XIMG is an existing XImage
8646 object to use for the heuristic. */
8648 unsigned long
8653 {
8655 /* IMG doesn't have a background yet, try to guess a reasonable value. */
8656 {
8670 #endif
8671 }
8674 }
8676 /* Return the `background_transparent' field of IMG. If IMG doesn't
8677 have one yet, it is guessed heuristically. If non-zero, MASK is an
8678 existing XImage object to use for the heuristic. */
8680 int
8685 {
8687 /* IMG doesn't have a background yet, try to guess a reasonable value. */
8688 {
8691 {
8698 img->background_transparent
8703 }
8704 else
8705 #endif
8709 }
8712 }
8714 \f
8715 /***********************************************************************
8716 Helper functions for X image types
8717 ***********************************************************************/
8724 Lisp_Object color_name,
8728 /* Clear X resources of image IMG on frame F. PIXMAP_P non-zero means
8729 free the pixmap if any. MASK_P non-zero means clear the mask
8730 pixmap if any. COLORS_P non-zero means free colors allocated for
8731 the image, if any. */
8733 static void
8738 {
8741 {
8745 }
8748 {
8752 }
8755 {
8760 }
8761 #endif
8762 }
8764 /* Free X resources of image IMG which is used on frame F. */
8766 static void
8770 {
8774 {
8775 BLOCK_INPUT;
8778 UNBLOCK_INPUT;
8779 }
8782 {
8785 /* If display has an immutable color map, freeing colors is not
8786 necessary and some servers don't allow it. So don't do it. */
8790 {
8791 Colormap cmap;
8792 BLOCK_INPUT;
8796 UNBLOCK_INPUT;
8797 }
8802 }
8803 #endif
8804 }
8807 /* Allocate color COLOR_NAME for image IMG on frame F. If color
8808 cannot be allocated, use DFLT. Add a newly allocated color to
8809 IMG->colors, so that it can be freed again. Value is the pixel
8810 color. */
8812 static unsigned long
8816 Lisp_Object color_name;
8818 {
8820 XColor color;
8826 {
8827 /* This isn't called frequently so we get away with simply
8828 reallocating the color vector to the needed size, here. */
8835 }
8836 else
8839 #endif
8841 }
8844 \f
8845 /***********************************************************************
8846 Image Cache
8847 ***********************************************************************/
8853 /* Return a new, initialized image cache that is allocated from the
8854 heap. Call free_image_cache to free an image cache. */
8858 {
8869 }
8872 /* Free image cache of frame F. Be aware that X frames share images
8873 caches. */
8875 void
8878 {
8881 {
8884 /* Cache should not be referenced by any frame when freed. */
8893 }
8894 }
8897 /* Clear image cache of frame F. FORCE_P non-zero means free all
8898 images. FORCE_P zero means clear only images that haven't been
8899 displayed for some time. Should be called from time to time to
8900 reduce the number of loaded images. If image-eviction-seconds is
8901 non-nil, this frees images in the cache which weren't displayed for
8902 at least that many seconds. */
8904 void
8908 {
8912 {
8913 EMACS_TIME t;
8921 {
8924 && (force_p
8926 {
8929 }
8930 }
8932 /* We may be clearing the image cache because, for example,
8933 Emacs was iconified for a longer period of time. In that
8934 case, current matrices may still contain references to
8935 images freed above. So, clear these matrices. */
8937 {
8940 }
8941 }
8942 }
8948 FRAME nil or omitted means use the selected frame.
8951 Lisp_Object frame;
8952 {
8954 {
8955 Lisp_Object tail;
8960 }
8961 else
8965 }
8968 /* Compute masks and transform image IMG on frame F, as specified
8969 by the image's specification, */
8971 static void
8975 {
8977 /* Manipulation of the image's mask. */
8979 {
8981 Lisp_Object mask;
8985 /* `:heuristic-mask t'
8986 `:mask heuristic'
8987 means build a mask heuristically.
8988 `:heuristic-mask (R G B)'
8989 `:mask (heuristic (R G B))'
8990 means build a mask from color (R G B) in the
8991 image.
8992 `:mask nil'
8993 means remove a mask, if any. */
8998 else
8999 {
9008 {
9011 else
9013 }
9015 {
9018 }
9019 }
9022 /* Should we apply an image transformation algorithm? */
9032 {
9033 Lisp_Object tem;
9039 }
9040 }
9041 #endif
9042 }
9045 /* Return the id of image with Lisp specification SPEC on frame F.
9046 SPEC must be a valid Lisp image specification (see valid_image_p). */
9048 int
9051 Lisp_Object spec;
9052 {
9058 EMACS_TIME now;
9060 /* F must be a window-system frame, and SPEC must be a valid image
9061 specification. */
9067 /* Look up SPEC in the hash table of the image cache. */
9075 /* If not found, create a new image and cache it. */
9077 {
9080 BLOCK_INPUT;
9085 /* If we can't load the image, and we don't have a width and
9086 height, use some arbitrary width and height so that we can
9087 draw a rectangle for it. */
9089 {
9090 Lisp_Object value;
9098 }
9099 else
9100 {
9101 /* Handle image type independent image attributes
9102 `:ascent PERCENT', `:margin MARGIN', `:relief RELIEF',
9103 `:background COLOR'. */
9117 {
9122 }
9126 {
9130 }
9133 {
9136 {
9137 img->background
9141 }
9142 }
9144 /* Do image transformations and compute masks, unless we
9145 don't have the image yet. */
9148 }
9150 UNBLOCK_INPUT;
9152 }
9154 /* We're using IMG, so set its timestamp to `now'. */
9158 UNGCPRO;
9160 /* Value is the image id. */
9162 }
9165 /* Cache image IMG in the image cache of frame F. */
9167 static void
9171 {
9175 /* Find a free slot in c->images. */
9180 /* If no free slot found, maybe enlarge c->images. */
9182 {
9186 }
9188 /* Add IMG to c->images, and assign IMG an id. */
9194 /* Add IMG to the cache's hash table. */
9201 }
9204 /* Call FN on every image in the image cache of frame F. Used to mark
9205 Lisp Objects in the image cache. */
9207 void
9211 {
9213 {
9216 {
9221 }
9222 }
9223 }
9226 \f
9227 /***********************************************************************
9228 W32 support code
9229 ***********************************************************************/
9239 /* Create an XImage and a pixmap of size WIDTH x HEIGHT for use on
9240 frame F. Set *XIMG and *PIXMAP to the XImage and Pixmap created.
9241 Set (*XIMG)->data to a raster of WIDTH x HEIGHT pixels allocated
9242 via xmalloc. Print error messages via image_error if an error
9243 occurs. Value is non-zero if successful. */
9245 static int
9251 {
9265 {
9268 }
9270 /* Allocate image raster. */
9273 /* Allocate a pixmap of the same size. */
9276 {
9281 }
9282 #endif
9284 }
9287 /* Destroy XImage XIMG. Free XIMG->data. */
9289 static void
9292 {
9295 {
9299 }
9300 }
9303 /* Put XImage XIMG into pixmap PIXMAP on frame F. WIDTH and HEIGHT
9304 are width and height of both the image and pixmap. */
9306 static void
9310 Pixmap pixmap;
9311 {
9312 GC gc;
9318 }
9320 #endif
9322 \f
9323 /***********************************************************************
9324 File Handling
9325 ***********************************************************************/
9331 /* Find image file FILE. Look in data-directory, then
9332 x-bitmap-file-path. Value is the full name of the file found, or
9333 nil if not found. */
9335 static Lisp_Object
9337 Lisp_Object file;
9338 {
9347 /* Try to find FILE in data-directory, then x-bitmap-file-path. */
9352 else
9355 UNGCPRO;
9357 }
9360 /* Read FILE into memory. Value is a pointer to a buffer allocated
9361 with xmalloc holding FILE's contents. Value is null if an error
9362 occurred. *SIZE is set to the size of the file. */
9368 {
9377 {
9380 }
9381 else
9382 {
9386 {
9389 }
9390 }
9393 }
9396 \f
9397 /***********************************************************************
9398 XBM images
9399 ***********************************************************************/
9403 Lisp_Object file));
9409 /* Indices of image specification fields in xbm_format, below. */
9411 enum xbm_keyword_index
9412 {
9413 XBM_TYPE,
9414 XBM_FILE,
9415 XBM_WIDTH,
9416 XBM_HEIGHT,
9417 XBM_DATA,
9418 XBM_FOREGROUND,
9419 XBM_BACKGROUND,
9420 XBM_ASCENT,
9421 XBM_MARGIN,
9422 XBM_RELIEF,
9423 XBM_ALGORITHM,
9424 XBM_HEURISTIC_MASK,
9425 XBM_MASK,
9426 XBM_LAST
9427 };
9429 /* Vector of image_keyword structures describing the format
9430 of valid XBM image specifications. */
9433 {
9446 };
9448 /* Structure describing the image type XBM. */
9451 {
9453 xbm_image_p,
9454 xbm_load,
9455 x_clear_image,
9456 NULL
9457 };
9459 /* Tokens returned from xbm_scan. */
9461 enum xbm_token
9462 {
9464 XBM_TK_NUMBER
9465 };
9468 /* Return non-zero if OBJECT is a valid XBM-type image specification.
9469 A valid specification is a list starting with the symbol `image'
9470 The rest of the list is a property list which must contain an
9471 entry `:type xbm..
9473 If the specification specifies a file to load, it must contain
9474 an entry `:file FILENAME' where FILENAME is a string.
9476 If the specification is for a bitmap loaded from memory it must
9477 contain `:width WIDTH', `:height HEIGHT', and `:data DATA', where
9478 WIDTH and HEIGHT are integers > 0. DATA may be:
9480 1. a string large enough to hold the bitmap data, i.e. it must
9481 have a size >= (WIDTH + 7) / 8 * HEIGHT
9483 2. a bool-vector of size >= WIDTH * HEIGHT
9485 3. a vector of strings or bool-vectors, one for each line of the
9486 bitmap.
9488 Both the file and data forms may contain the additional entries
9489 `:background COLOR' and `:foreground COLOR'. If not present,
9490 foreground and background of the frame on which the image is
9491 displayed, is used. */
9493 static int
9495 Lisp_Object object;
9496 {
9506 {
9509 }
9510 else
9511 {
9512 Lisp_Object data;
9515 /* Entries for `:width', `:height' and `:data' must be present. */
9525 /* Check type of data, and width and height against contents of
9526 data. */
9528 {
9531 /* Number of elements of the vector must be >= height. */
9535 /* Each string or bool-vector in data must be large enough
9536 for one line of the image. */
9538 {
9542 {
9546 }
9548 {
9551 }
9552 else
9554 }
9555 }
9557 {
9561 }
9563 {
9566 }
9567 else
9569 }
9571 /* Baseline must be a value between 0 and 100 (a percentage). */
9577 }
9580 /* Scan a bitmap file. FP is the stream to read from. Value is
9581 either an enumerator from enum xbm_token, or a character for a
9582 single-character token, or 0 at end of file. If scanning an
9583 identifier, store the lexeme of the identifier in SVAL. If
9584 scanning a number, store its value in *IVAL. */
9586 static int
9591 {
9594 loop:
9596 /* Skip white space. */
9598 ;
9603 {
9607 {
9610 {
9612 {
9620 else
9623 }
9624 }
9626 {
9631 }
9632 }
9633 else
9634 {
9639 }
9645 }
9647 {
9656 }
9658 {
9659 /* C-style comment. */
9664 {
9667 }
9668 }
9671 }
9674 /* Replacement for XReadBitmapFileData which isn't available under old
9675 X versions. CONTENTS is a pointer to a buffer to parse; END is the
9676 buffer's end. Set *WIDTH and *HEIGHT to the width and height of
9677 the image. Return in *DATA the bitmap data allocated with xmalloc.
9678 Value is non-zero if successful. DATA null means just test if
9679 CONTENTS looks like an in-memory XBM file. */
9681 static int
9686 {
9696 #define match() \
9697 LA1 = xbm_scan (contents, end, buffer, &value)
9699 #define expect(TOKEN) \
9700 if (LA1 != (TOKEN)) \
9701 goto failure; \
9702 else \
9703 match ()
9705 #define expect_ident(IDENT) \
9706 if (LA1 == XBM_TK_IDENT && strcmp (buffer, (IDENT)) == 0) \
9707 match (); \
9708 else \
9709 goto failure
9716 /* Parse defines for width, height and hot-spots. */
9718 {
9724 {
9731 }
9733 }
9740 /* Parse bits. Must start with `static'. */
9743 {
9745 {
9748 }
9750 {
9755 }
9758 else
9760 }
9761 else
9775 {
9778 {
9788 else
9790 }
9791 }
9792 else
9793 {
9795 {
9803 else
9805 }
9806 }
9808 success:
9811 failure:
9814 {
9817 }
9820 #undef match
9821 #undef expect
9822 #undef expect_ident
9823 }
9826 /* Load XBM image IMG which will be displayed on frame F from buffer
9827 CONTENTS. END is the end of the buffer. Value is non-zero if
9828 successful. */
9830 static int
9835 {
9842 {
9846 Lisp_Object value;
9850 /* Get foreground and background colors, maybe allocate colors. */
9856 {
9860 }
9863 img->pixmap
9866 data,
9869 depth);
9870 #endif
9874 {
9877 }
9878 else
9880 }
9881 else
9885 }
9888 /* Value is non-zero if DATA looks like an in-memory XBM file. */
9890 static int
9892 Lisp_Object data;
9893 {
9900 }
9903 /* Fill image IMG which is used on frame F with pixmap data. Value is
9904 non-zero if successful. */
9906 static int
9910 {
9912 Lisp_Object file_name;
9916 /* If IMG->spec specifies a file name, create a non-file spec from it. */
9919 {
9920 Lisp_Object file;
9928 {
9930 UNGCPRO;
9932 }
9936 {
9938 UNGCPRO;
9940 }
9943 UNGCPRO;
9944 }
9945 else
9946 {
9948 Lisp_Object data;
9956 /* See if data looks like an in-memory XBM file. */
9960 /* Parse the list specification. */
9965 /* Get specified width, and height. */
9967 {
9971 }
9972 /* Get foreground and background colors, maybe allocate colors. */
9976 foreground);
9980 background);
9986 else
9987 {
9989 {
9996 {
10000 else
10002 }
10003 }
10006 else
10009 /* Create the pixmap. */
10011 img->pixmap
10014 bits,
10017 depth);
10018 #endif
10021 else
10022 {
10026 }
10027 }
10028 }
10031 }
10034 \f
10035 /***********************************************************************
10036 XPM images
10037 ***********************************************************************/
10039 #if HAVE_XPM
10047 /* The symbol `xpm' identifying XPM-format images. */
10049 Lisp_Object Qxpm;
10051 /* Indices of image specification fields in xpm_format, below. */
10053 enum xpm_keyword_index
10054 {
10055 XPM_TYPE,
10056 XPM_FILE,
10057 XPM_DATA,
10058 XPM_ASCENT,
10059 XPM_MARGIN,
10060 XPM_RELIEF,
10061 XPM_ALGORITHM,
10062 XPM_HEURISTIC_MASK,
10063 XPM_MASK,
10064 XPM_COLOR_SYMBOLS,
10065 XPM_BACKGROUND,
10066 XPM_LAST
10067 };
10069 /* Vector of image_keyword structures describing the format
10070 of valid XPM image specifications. */
10073 {
10085 };
10087 /* Structure describing the image type XBM. */
10090 {
10092 xpm_image_p,
10093 xpm_load,
10094 x_clear_image,
10095 NULL
10096 };
10099 /* Value is non-zero if COLOR_SYMBOLS is a valid color symbols list
10100 for XPM images. Such a list must consist of conses whose car and
10101 cdr are strings. */
10103 static int
10105 Lisp_Object color_symbols;
10106 {
10108 {
10115 }
10118 }
10121 /* Value is non-zero if OBJECT is a valid XPM image specification. */
10123 static int
10125 Lisp_Object object;
10126 {
10130 /* Either `:file' or `:data' must be present. */
10132 /* Either no `:color-symbols' or it's a list of conses
10133 whose car and cdr are strings. */
10138 }
10141 /* Load image IMG which will be displayed on frame F. Value is
10142 non-zero if successful. */
10144 static int
10148 {
10150 XpmAttributes attrs;
10153 /* Configure the XPM lib. Use the visual of frame F. Allocate
10154 close colors. Return colors allocated. */
10161 #ifdef XpmAllocCloseColors
10164 #else
10167 #endif
10169 /* If image specification contains symbolic color definitions, add
10170 these to `attrs'. */
10173 {
10174 Lisp_Object tail;
10180 /* Count number of symbols. */
10185 /* Allocate an XpmColorSymbol array. */
10191 /* Fill the color symbol array. */
10195 {
10202 }
10203 }
10205 /* Create a pixmap for the image, either from a file, or from a
10206 string buffer containing data in the same format as an XPM file. */
10207 BLOCK_INPUT;
10210 {
10213 {
10215 UNBLOCK_INPUT;
10217 }
10222 }
10223 else
10224 {
10230 }
10231 UNBLOCK_INPUT;
10234 {
10235 /* Remember allocated colors. */
10246 /* The call to XpmFreeAttributes below frees attrs.alloc_pixels. */
10247 BLOCK_INPUT;
10249 UNBLOCK_INPUT;
10250 }
10251 else
10252 {
10254 {
10274 }
10275 }
10278 }
10282 \f
10284 /***********************************************************************
10285 Color table
10286 ***********************************************************************/
10288 /* An entry in the color table mapping an RGB color to a pixel color. */
10290 struct ct_color
10291 {
10295 /* Next in color table collision list. */
10297 };
10299 /* The bucket vector size to use. Must be prime. */
10301 #define CT_SIZE 101
10303 /* Value is a hash of the RGB color given by R, G, and B. */
10305 #define CT_HASH_RGB(R, G, B) (((R) << 16) ^ ((G) << 8) ^ (B))
10307 /* The color hash table. */
10311 /* Number of entries in the color table. */
10315 /* Function prototypes. */
10324 /* Initialize the color table. */
10326 static void
10328 {
10333 }
10336 /* Free memory associated with the color table. */
10338 static void
10340 {
10346 {
10349 }
10353 }
10356 /* Value is a pixel color for RGB color R, G, B on frame F. If an
10357 entry for that color already is in the color table, return the
10358 pixel color of that entry. Otherwise, allocate a new color for R,
10359 G, B, and make an entry in the color table. */
10361 static unsigned long
10365 {
10375 {
10376 COLORREF color;
10377 Colormap cmap;
10391 }
10394 }
10397 /* Look up pixel color PIXEL which is used on frame F in the color
10398 table. If not already present, allocate it. Value is PIXEL. */
10400 static unsigned long
10404 {
10413 {
10414 XColor color;
10415 Colormap cmap;
10418 BLOCK_INPUT;
10424 UNBLOCK_INPUT;
10427 {
10437 }
10438 else
10440 }
10442 }
10445 /* Value is a vector of all pixel colors contained in the color table,
10446 allocated via xmalloc. Set *N to the number of colors. */
10451 {
10457 {
10460 }
10461 else
10462 {
10470 }
10473 }
10477 \f
10478 /***********************************************************************
10479 Algorithms
10480 ***********************************************************************/
10486 /* Non-zero means draw a cross on images having `:conversion
10487 disabled'. */
10491 /* Edge detection matrices for different edge-detection
10492 strategies. */
10495 /* x - 1 x x + 1 */
10499 };
10502 /* x - 1 x x + 1 */
10506 };
10508 /* Value is the intensity of the color whose red/green/blue values
10509 are R, G, and B. */
10511 #define COLOR_INTENSITY(R, G, B) ((2 * (R) + 3 * (G) + (B)) / 6)
10514 /* On frame F, return an array of XColor structures describing image
10515 IMG->pixmap. Each XColor structure has its pixel color set. RGB_P
10516 non-zero means also fill the red/green/blue members of the XColor
10517 structures. Value is a pointer to the array of XColors structures,
10518 allocated with xmalloc; it must be freed by the caller. */
10525 {
10532 /* Get the X image IMG->pixmap. */
10536 /* Fill the `pixel' members of the XColor array. I wished there
10537 were an easy and portable way to circumvent XGetPixel. */
10540 {
10548 }
10552 }
10555 /* Create IMG->pixmap from an array COLORS of XColor structures, whose
10556 RGB members are set. F is the frame on which this all happens.
10557 COLORS will be freed; an existing IMG->pixmap will be freed, too. */
10559 static void
10564 {
10567 Pixmap pixmap;
10577 {
10581 }
10591 }
10594 /* On frame F, perform edge-detection on image IMG.
10596 MATRIX is a nine-element array specifying the transformation
10597 matrix. See emboss_matrix for an example.
10599 COLOR_ADJUST is a color adjustment added to each pixel of the
10600 outgoing image. */
10602 static void
10607 {
10615 #define COLOR(A, X, Y) ((A) + (Y) * img->width + (X))
10620 {
10625 }
10628 {
10633 }
10636 {
10640 {
10647 {
10652 }
10658 }
10659 }
10664 #undef COLOR
10665 }
10668 /* Perform the pre-defined `emboss' edge-detection on image IMG
10669 on frame F. */
10671 static void
10675 {
10677 }
10680 /* Transform image IMG which is used on frame F with a Laplace
10681 edge-detection algorithm. The result is an image that can be used
10682 to draw disabled buttons, for example. */
10684 static void
10688 {
10690 }
10693 /* Perform edge-detection on image IMG on frame F, with specified
10694 transformation matrix MATRIX and color-adjustment COLOR_ADJUST.
10696 MATRIX must be either
10698 - a list of at least 9 numbers in row-major form
10699 - a vector of at least 9 numbers
10701 COLOR_ADJUST nil means use a default; otherwise it must be a
10702 number. */
10704 static void
10709 {
10714 {
10719 }
10721 {
10724 }
10731 }
10734 /* Transform image IMG on frame F so that it looks disabled. */
10736 static void
10740 {
10744 {
10745 /* Color (or grayscale). Convert to gray, and equalize. Just
10746 drawing such images with a stipple can look very odd, so
10747 we're using this method instead. */
10756 {
10760 }
10763 }
10765 /* Draw a cross over the disabled image, if we must or if we
10766 should. */
10768 {
10770 GC gc;
10781 {
10789 }
10790 }
10791 }
10794 /* Build a mask for image IMG which is used on frame F. FILE is the
10795 name of an image file, for error messages. HOW determines how to
10796 determine the background color of IMG. If it is a list '(R G B)',
10797 with R, G, and B being integers >= 0, take that as the color of the
10798 background. Otherwise, determine the background color of IMG
10799 heuristically. Value is non-zero if successful. */
10801 static int
10805 Lisp_Object how;
10806 {
10813 {
10817 }
10819 /* Create an image and pixmap serving as mask. */
10825 /* Get the X image of IMG->pixmap. */
10829 /* Determine the background color of ximg. If HOW is `(R G B)'
10830 take that as color. Otherwise, use the image's background color. */
10834 {
10838 {
10841 }
10844 {
10849 }
10850 }
10855 /* Set all bits in mask_img to 1 whose color in ximg is different
10856 from the background color bg. */
10861 /* Fill in the background_transparent field while we have the mask handy. */
10864 /* Put mask_img into img->mask. */
10870 }
10873 \f
10874 /***********************************************************************
10875 PBM (mono, gray, color)
10876 ***********************************************************************/
10877 #ifdef HAVE_PBM
10883 /* The symbol `pbm' identifying images of this type. */
10885 Lisp_Object Qpbm;
10887 /* Indices of image specification fields in gs_format, below. */
10889 enum pbm_keyword_index
10890 {
10891 PBM_TYPE,
10892 PBM_FILE,
10893 PBM_DATA,
10894 PBM_ASCENT,
10895 PBM_MARGIN,
10896 PBM_RELIEF,
10897 PBM_ALGORITHM,
10898 PBM_HEURISTIC_MASK,
10899 PBM_MASK,
10900 PBM_FOREGROUND,
10901 PBM_BACKGROUND,
10902 PBM_LAST
10903 };
10905 /* Vector of image_keyword structures describing the format
10906 of valid user-defined image specifications. */
10909 {
10921 };
10923 /* Structure describing the image type `pbm'. */
10926 {
10928 pbm_image_p,
10929 pbm_load,
10930 x_clear_image,
10931 NULL
10932 };
10935 /* Return non-zero if OBJECT is a valid PBM image specification. */
10937 static int
10939 Lisp_Object object;
10940 {
10950 /* Must specify either :data or :file. */
10952 }
10955 /* Scan a decimal number from *S and return it. Advance *S while
10956 reading the number. END is the end of the string. Value is -1 at
10957 end of input. */
10959 static int
10962 {
10966 {
10967 /* Skip white-space. */
10969 ;
10972 {
10973 /* Skip comment to end of line. */
10975 ;
10976 }
10978 {
10979 /* Read decimal number. */
10984 }
10985 else
10987 }
10990 }
10993 /* Read FILE into memory. Value is a pointer to a buffer allocated
10994 with xmalloc holding FILE's contents. Value is null if an error
10995 occured. *SIZE is set to the size of the file. */
10999 Lisp_Object file;
11001 {
11010 {
11013 }
11014 else
11015 {
11019 {
11022 }
11023 }
11026 }
11029 /* Load PBM image IMG for use on frame F. */
11031 static int
11035 {
11051 {
11054 {
11056 UNGCPRO;
11058 }
11062 {
11064 UNGCPRO;
11066 }
11070 }
11071 else
11072 {
11073 Lisp_Object data;
11077 }
11079 /* Check magic number. */
11081 {
11083 error:
11085 UNGCPRO;
11087 }
11090 {
11118 }
11120 /* Read width, height, maximum color-component. Characters
11121 starting with `#' up to the end of a line are ignored. */
11126 {
11130 }
11141 /* Initialize the color hash table. */
11145 {
11151 /* Parse the image specification. */
11155 /* Get foreground and background colors, maybe allocate colors. */
11161 {
11165 }
11169 {
11171 {
11176 }
11177 else
11181 }
11182 }
11183 else
11184 {
11187 {
11193 {
11197 }
11198 else
11199 {
11203 }
11206 {
11213 }
11215 /* RGB values are now in the range 0..max_color_idx.
11216 Scale this to the range 0..0xffff supported by X. */
11221 }
11222 }
11224 /* Store in IMG->colors the colors allocated for the image, and
11225 free the color table. */
11229 /* Maybe fill in the background field while we have ximg handy. */
11233 /* Put the image into a pixmap. */
11240 UNGCPRO;
11243 }
11246 \f
11247 /***********************************************************************
11248 PNG
11249 ***********************************************************************/
11251 #if HAVE_PNG
11253 #include <png.h>
11255 /* Function prototypes. */
11260 /* The symbol `png' identifying images of this type. */
11262 Lisp_Object Qpng;
11264 /* Indices of image specification fields in png_format, below. */
11266 enum png_keyword_index
11267 {
11268 PNG_TYPE,
11269 PNG_DATA,
11270 PNG_FILE,
11271 PNG_ASCENT,
11272 PNG_MARGIN,
11273 PNG_RELIEF,
11274 PNG_ALGORITHM,
11275 PNG_HEURISTIC_MASK,
11276 PNG_MASK,
11277 PNG_BACKGROUND,
11278 PNG_LAST
11279 };
11281 /* Vector of image_keyword structures describing the format
11282 of valid user-defined image specifications. */
11285 {
11296 };
11298 /* Structure describing the image type `png'. */
11301 {
11303 png_image_p,
11304 png_load,
11305 x_clear_image,
11306 NULL
11307 };
11310 /* Return non-zero if OBJECT is a valid PNG image specification. */
11312 static int
11314 Lisp_Object object;
11315 {
11324 /* Must specify either the :data or :file keyword. */
11326 }
11329 /* Error and warning handlers installed when the PNG library
11330 is initialized. */
11332 static void
11336 {
11340 }
11343 static void
11347 {
11350 }
11352 /* Memory source for PNG decoding. */
11354 struct png_memory_storage
11355 {
11359 };
11362 /* Function set as reader function when reading PNG image from memory.
11363 PNG_PTR is a pointer to the PNG control structure. Copy LENGTH
11364 bytes from the input to DATA. */
11366 static void
11368 png_structp png_ptr;
11369 png_bytep data;
11370 png_size_t length;
11371 {
11380 }
11382 /* Load PNG image IMG for use on frame F. Value is non-zero if
11383 successful. */
11385 static int
11389 {
11391 Lisp_Object specified_data;
11403 png_byte channels;
11404 png_uint_32 row_bytes;
11411 /* Find out what file to load. */
11418 {
11421 {
11423 UNGCPRO;
11425 }
11427 /* Open the image file. */
11430 {
11432 UNGCPRO;
11435 }
11437 /* Check PNG signature. */
11440 {
11442 UNGCPRO;
11445 }
11446 }
11447 else
11448 {
11449 /* Read from memory. */
11454 /* Check PNG signature. */
11457 {
11459 UNGCPRO;
11461 }
11463 /* Need to skip past the signature. */
11465 }
11467 /* Initialize read and info structs for PNG lib. */
11471 {
11473 UNGCPRO;
11475 }
11479 {
11482 UNGCPRO;
11484 }
11488 {
11491 UNGCPRO;
11493 }
11495 /* Set error jump-back. We come back here when the PNG library
11496 detects an error. */
11498 {
11499 error:
11505 UNGCPRO;
11507 }
11509 /* Read image info. */
11512 else
11520 /* If image contains simply transparency data, we prefer to
11521 construct a clipping mask. */
11524 else
11527 /* This function is easier to write if we only have to handle
11528 one data format: RGB or RGBA with 8 bits per channel. Let's
11529 transform other formats into that format. */
11531 /* Strip more than 8 bits per channel. */
11535 /* Expand data to 24 bit RGB, or 8 bit grayscale, with alpha channel
11536 if available. */
11539 /* Convert grayscale images to RGB. */
11544 /* The value 2.2 is a guess for PC monitors from PNG example.c. */
11548 /* Tell the PNG lib to handle gamma correction for us. */
11550 #if defined(PNG_READ_sRGB_SUPPORTED) || defined(PNG_WRITE_sRGB_SUPPORTED)
11552 /* There is a special chunk in the image specifying the gamma. */
11554 else
11555 #endif
11557 /* Image contains gamma information. */
11559 else
11560 /* Use a default of 0.5 for the image gamma. */
11563 /* Handle alpha channel by combining the image with a background
11564 color. Do this only if a real alpha channel is supplied. For
11565 simple transparency, we prefer a clipping mask. */
11567 {
11569 Lisp_Object specified_bg
11574 /* The user specified `:background', use that. */
11575 {
11576 COLORREF color;
11578 {
11579 png_color_16 user_bg;
11588 }
11589 }
11591 /* Image contains a background color with which to
11592 combine the image. */
11595 else
11596 {
11597 /* Image does not contain a background color with which
11598 to combine the image data via an alpha channel. Use
11599 the frame's background instead. */
11600 XColor color;
11601 Colormap cmap;
11602 png_color_16 frame_background;
11615 }
11616 }
11618 /* Update info structure. */
11621 /* Get number of channels. Valid values are 1 for grayscale images
11622 and images with a palette, 2 for grayscale images with transparency
11623 information (alpha channel), 3 for RGB images, and 4 for RGB
11624 images with alpha channel, i.e. RGBA. If conversions above were
11625 sufficient we should only have 3 or 4 channels here. */
11629 /* Number of bytes needed for one row of the image. */
11632 /* Allocate memory for the image. */
11638 /* Read the entire image. */
11642 {
11645 }
11647 /* Create the X image and pixmap. */
11652 /* Create an image and pixmap serving as mask if the PNG image
11653 contains an alpha channel. */
11655 && !transparent_p
11658 {
11663 }
11665 /* Fill the X image and mask from PNG data. */
11669 {
11673 {
11681 /* An alpha channel, aka mask channel, associates variable
11682 transparency with an image. Where other image formats
11683 support binary transparency---fully transparent or fully
11684 opaque---PNG allows up to 254 levels of partial transparency.
11685 The PNG library implements partial transparency by combining
11686 the image with a specified background color.
11688 I'm not sure how to handle this here nicely: because the
11689 background on which the image is displayed may change, for
11690 real alpha channel support, it would be necessary to create
11691 a new image for each possible background.
11693 What I'm doing now is that a mask is created if we have
11694 boolean transparency information. Otherwise I'm using
11695 the frame's background color to combine the image with. */
11698 {
11702 }
11703 }
11704 }
11707 /* Set IMG's background color from the PNG image, unless the user
11708 overrode it. */
11709 {
11712 {
11715 }
11716 }
11718 /* Remember colors allocated for this image. */
11722 /* Clean up. */
11730 /* Maybe fill in the background field while we have ximg handy. */
11733 /* Put the image into the pixmap, then free the X image and its buffer. */
11737 /* Same for the mask. */
11739 {
11740 /* Fill in the background_transparent field while we have the mask
11741 handy. */
11746 }
11748 UNGCPRO;
11750 }
11755 \f
11756 /***********************************************************************
11757 JPEG
11758 ***********************************************************************/
11760 #if HAVE_JPEG
11762 /* Work around a warning about HAVE_STDLIB_H being redefined in
11763 jconfig.h. */
11764 #ifdef HAVE_STDLIB_H
11765 #define HAVE_STDLIB_H_1
11766 #undef HAVE_STDLIB_H
11769 #include <jpeglib.h>
11770 #include <jerror.h>
11771 #include <setjmp.h>
11773 #ifdef HAVE_STLIB_H_1
11774 #define HAVE_STDLIB_H 1
11775 #endif
11780 /* The symbol `jpeg' identifying images of this type. */
11782 Lisp_Object Qjpeg;
11784 /* Indices of image specification fields in gs_format, below. */
11786 enum jpeg_keyword_index
11787 {
11788 JPEG_TYPE,
11789 JPEG_DATA,
11790 JPEG_FILE,
11791 JPEG_ASCENT,
11792 JPEG_MARGIN,
11793 JPEG_RELIEF,
11794 JPEG_ALGORITHM,
11795 JPEG_HEURISTIC_MASK,
11796 JPEG_MASK,
11797 JPEG_BACKGROUND,
11798 JPEG_LAST
11799 };
11801 /* Vector of image_keyword structures describing the format
11802 of valid user-defined image specifications. */
11805 {
11816 };
11818 /* Structure describing the image type `jpeg'. */
11821 {
11823 jpeg_image_p,
11824 jpeg_load,
11825 x_clear_image,
11826 NULL
11827 };
11830 /* Return non-zero if OBJECT is a valid JPEG image specification. */
11832 static int
11834 Lisp_Object object;
11835 {
11845 /* Must specify either the :data or :file keyword. */
11847 }
11850 struct my_jpeg_error_mgr
11851 {
11854 };
11856 static void
11858 j_common_ptr cinfo;
11859 {
11862 }
11864 /* Init source method for JPEG data source manager. Called by
11865 jpeg_read_header() before any data is actually read. See
11866 libjpeg.doc from the JPEG lib distribution. */
11868 static void
11870 j_decompress_ptr cinfo;
11871 {
11872 }
11875 /* Fill input buffer method for JPEG data source manager. Called
11876 whenever more data is needed. We read the whole image in one step,
11877 so this only adds a fake end of input marker at the end. */
11879 static boolean
11881 j_decompress_ptr cinfo;
11882 {
11883 /* Insert a fake EOI marker. */
11893 }
11896 /* Method to skip over NUM_BYTES bytes in the image data. CINFO->src
11897 is the JPEG data source manager. */
11899 static void
11901 j_decompress_ptr cinfo;
11903 {
11907 {
11913 }
11914 }
11917 /* Method to terminate data source. Called by
11918 jpeg_finish_decompress() after all data has been processed. */
11920 static void
11922 j_decompress_ptr cinfo;
11923 {
11924 }
11927 /* Set up the JPEG lib for reading an image from DATA which contains
11928 LEN bytes. CINFO is the decompression info structure created for
11929 reading the image. */
11931 static void
11933 j_decompress_ptr cinfo;
11936 {
11940 {
11941 /* First time for this JPEG object? */
11947 }
11957 }
11960 /* Load image IMG for use on frame F. Patterned after example.c
11961 from the JPEG lib. */
11963 static int
11967 {
11971 Lisp_Object specified_data;
11973 JSAMPARRAY buffer;
11981 /* Open the JPEG file. */
11988 {
11991 {
11993 UNGCPRO;
11995 }
11999 {
12001 UNGCPRO;
12003 }
12004 }
12006 /* Customize libjpeg's error handling to call my_error_exit when an
12007 error is detected. This function will perform a longjmp. */
12012 {
12014 {
12015 /* Called from my_error_exit. Display a JPEG error. */
12020 }
12022 /* Close the input file and destroy the JPEG object. */
12027 /* If we already have an XImage, free that. */
12030 /* Free pixmap and colors. */
12033 UNGCPRO;
12035 }
12037 /* Create the JPEG decompression object. Let it read from fp.
12038 Read the JPEG image header. */
12043 else
12049 /* Customize decompression so that color quantization will be used.
12050 Start decompression. */
12056 /* Create X image and pixmap. */
12061 /* Allocate colors. When color quantization is used,
12062 cinfo.actual_number_of_colors has been set with the number of
12063 colors generated, and cinfo.colormap is a two-dimensional array
12064 of color indices in the range 0..cinfo.actual_number_of_colors.
12065 No more than 255 colors will be generated. */
12066 {
12073 else
12076 /* Use the color table mechanism because it handles colors that
12077 cannot be allocated nicely. Such colors will be replaced with
12078 a default color, and we don't have to care about which colors
12079 can be freed safely, and which can't. */
12085 {
12086 /* Multiply RGB values with 255 because X expects RGB values
12087 in the range 0..0xffff. */
12092 }
12094 /* Remember those colors actually allocated. */
12097 }
12099 /* Read pixels. */
12104 {
12108 }
12110 /* Clean up. */
12116 /* Maybe fill in the background field while we have ximg handy. */
12120 /* Put the image into the pixmap. */
12123 UNBLOCK_INPUT;
12124 UNGCPRO;
12126 }
12131 \f
12132 /***********************************************************************
12133 TIFF
12134 ***********************************************************************/
12136 #if HAVE_TIFF
12138 #include <tiffio.h>
12143 /* The symbol `tiff' identifying images of this type. */
12145 Lisp_Object Qtiff;
12147 /* Indices of image specification fields in tiff_format, below. */
12149 enum tiff_keyword_index
12150 {
12151 TIFF_TYPE,
12152 TIFF_DATA,
12153 TIFF_FILE,
12154 TIFF_ASCENT,
12155 TIFF_MARGIN,
12156 TIFF_RELIEF,
12157 TIFF_ALGORITHM,
12158 TIFF_HEURISTIC_MASK,
12159 TIFF_MASK,
12160 TIFF_BACKGROUND,
12161 TIFF_LAST
12162 };
12164 /* Vector of image_keyword structures describing the format
12165 of valid user-defined image specifications. */
12168 {
12179 };
12181 /* Structure describing the image type `tiff'. */
12184 {
12186 tiff_image_p,
12187 tiff_load,
12188 x_clear_image,
12189 NULL
12190 };
12193 /* Return non-zero if OBJECT is a valid TIFF image specification. */
12195 static int
12197 Lisp_Object object;
12198 {
12207 /* Must specify either the :data or :file keyword. */
12209 }
12212 /* Reading from a memory buffer for TIFF images Based on the PNG
12213 memory source, but we have to provide a lot of extra functions.
12214 Blah.
12216 We really only need to implement read and seek, but I am not
12217 convinced that the TIFF library is smart enough not to destroy
12218 itself if we only hand it the function pointers we need to
12219 override. */
12222 {
12226 }
12227 tiff_memory_source;
12229 static size_t
12231 thandle_t data;
12232 tdata_t buf;
12233 tsize_t size;
12234 {
12242 }
12244 static size_t
12246 thandle_t data;
12247 tdata_t buf;
12248 tsize_t size;
12249 {
12251 }
12253 static toff_t
12255 thandle_t data;
12256 toff_t off;
12258 {
12263 {
12278 }
12285 }
12287 static int
12289 thandle_t data;
12290 {
12291 /* NOOP */
12293 }
12295 static int
12297 thandle_t data;
12300 {
12301 /* It is already _IN_ memory. */
12303 }
12305 static void
12307 thandle_t data;
12308 tdata_t base;
12309 toff_t size;
12310 {
12311 /* We don't need to do this. */
12312 }
12314 static toff_t
12316 thandle_t data;
12317 {
12319 }
12322 static void
12326 {
12333 }
12336 static void
12340 {
12347 }
12350 /* Load TIFF image IMG for use on frame F. Value is non-zero if
12351 successful. */
12353 static int
12357 {
12359 Lisp_Object specified_data;
12366 tiff_memory_source memsrc;
12377 {
12378 /* Read from a file */
12381 {
12383 UNGCPRO;
12385 }
12387 /* Try to open the image file. */
12390 {
12392 UNGCPRO;
12394 }
12395 }
12396 else
12397 {
12398 /* Memory source! */
12406 tiff_seek_in_memory,
12407 tiff_close_memory,
12408 tiff_size_of_memory,
12409 tiff_mmap_memory,
12410 tiff_unmap_memory);
12413 {
12415 UNGCPRO;
12417 }
12418 }
12420 /* Get width and height of the image, and allocate a raster buffer
12421 of width x height 32-bit values. */
12429 {
12432 UNGCPRO;
12434 }
12436 /* Create the X image and pixmap. */
12438 {
12440 UNGCPRO;
12442 }
12444 /* Initialize the color table. */
12447 /* Process the pixel raster. Origin is in the lower-left corner. */
12449 {
12453 {
12459 }
12460 }
12462 /* Remember the colors allocated for the image. Free the color table. */
12469 /* Maybe fill in the background field while we have ximg handy. */
12473 /* Put the image into the pixmap, then free the X image and its buffer. */
12478 UNGCPRO;
12480 }
12485 \f
12486 /***********************************************************************
12487 GIF
12488 ***********************************************************************/
12490 #if HAVE_GIF
12492 #include <gif_lib.h>
12497 /* The symbol `gif' identifying images of this type. */
12499 Lisp_Object Qgif;
12501 /* Indices of image specification fields in gif_format, below. */
12503 enum gif_keyword_index
12504 {
12505 GIF_TYPE,
12506 GIF_DATA,
12507 GIF_FILE,
12508 GIF_ASCENT,
12509 GIF_MARGIN,
12510 GIF_RELIEF,
12511 GIF_ALGORITHM,
12512 GIF_HEURISTIC_MASK,
12513 GIF_MASK,
12514 GIF_IMAGE,
12515 GIF_BACKGROUND,
12516 GIF_LAST
12517 };
12519 /* Vector of image_keyword structures describing the format
12520 of valid user-defined image specifications. */
12523 {
12535 };
12537 /* Structure describing the image type `gif'. */
12540 {
12542 gif_image_p,
12543 gif_load,
12544 x_clear_image,
12545 NULL
12546 };
12548 /* Return non-zero if OBJECT is a valid GIF image specification. */
12550 static int
12552 Lisp_Object object;
12553 {
12562 /* Must specify either the :data or :file keyword. */
12564 }
12566 /* Reading a GIF image from memory
12567 Based on the PNG memory stuff to a certain extent. */
12570 {
12574 }
12575 gif_memory_source;
12577 /* Make the current memory source available to gif_read_from_memory.
12578 It's done this way because not all versions of libungif support
12579 a UserData field in the GifFileType structure. */
12582 static int
12587 {
12596 }
12599 /* Load GIF image IMG for use on frame F. Value is non-zero if
12600 successful. */
12602 static int
12606 {
12608 Lisp_Object specified_data;
12615 Lisp_Object image;
12617 gif_memory_source memsrc;
12626 {
12629 {
12631 UNGCPRO;
12633 }
12635 /* Open the GIF file. */
12638 {
12640 UNGCPRO;
12642 }
12643 }
12644 else
12645 {
12646 /* Read from memory! */
12654 {
12656 UNGCPRO;
12658 }
12659 }
12661 /* Read entire contents. */
12664 {
12667 UNGCPRO;
12669 }
12674 {
12678 UNGCPRO;
12680 }
12685 /* Create the X image and pixmap. */
12687 {
12689 UNGCPRO;
12691 }
12693 /* Allocate colors. */
12701 {
12706 }
12711 /* Clear the part of the screen image that are not covered by
12712 the image from the GIF file. Full animated GIF support
12713 requires more than can be done here (see the gif89 spec,
12714 disposal methods). Let's simply assume that the part
12715 not covered by a sub-image is in the frame's background color. */
12730 {
12735 }
12737 /* Read the GIF image into the X image. We use a local variable
12738 `raster' here because RasterBits below is a char *, and invites
12739 problems with bytes >= 0x80. */
12743 {
12752 {
12754 {
12758 }
12761 {
12765 }
12768 }
12769 }
12770 else
12771 {
12774 {
12777 }
12778 }
12782 /* Maybe fill in the background field while we have ximg handy. */
12786 /* Put the image into the pixmap, then free the X image and its buffer. */
12790 UNGCPRO;
12792 }
12797 \f
12798 /***********************************************************************
12799 Ghostscript
12800 ***********************************************************************/
12802 Lisp_Object Qpostscript;
12804 #ifdef HAVE_GHOSTSCRIPT
12809 /* The symbol `postscript' identifying images of this type. */
12811 /* Keyword symbols. */
12815 /* Indices of image specification fields in gs_format, below. */
12817 enum gs_keyword_index
12818 {
12819 GS_TYPE,
12820 GS_PT_WIDTH,
12821 GS_PT_HEIGHT,
12822 GS_FILE,
12823 GS_LOADER,
12824 GS_BOUNDING_BOX,
12825 GS_ASCENT,
12826 GS_MARGIN,
12827 GS_RELIEF,
12828 GS_ALGORITHM,
12829 GS_HEURISTIC_MASK,
12830 GS_MASK,
12831 GS_BACKGROUND,
12832 GS_LAST
12833 };
12835 /* Vector of image_keyword structures describing the format
12836 of valid user-defined image specifications. */
12839 {
12853 };
12855 /* Structure describing the image type `ghostscript'. */
12858 {
12860 gs_image_p,
12861 gs_load,
12862 gs_clear_image,
12863 NULL
12864 };
12867 /* Free X resources of Ghostscript image IMG which is used on frame F. */
12869 static void
12873 {
12874 /* IMG->data.ptr_val may contain a recorded colormap. */
12877 }
12880 /* Return non-zero if OBJECT is a valid Ghostscript image
12881 specification. */
12883 static int
12885 Lisp_Object object;
12886 {
12888 Lisp_Object tem;
12898 /* Bounding box must be a list or vector containing 4 integers. */
12901 {
12907 }
12909 {
12915 }
12916 else
12920 }
12923 /* Load Ghostscript image IMG for use on frame F. Value is non-zero
12924 if successful. */
12926 static int
12930 {
12934 Lisp_Object frame;
12938 /* Compute pixel size of pixmap needed from the given size in the
12939 image specification. Sizes in the specification are in pt. 1 pt
12940 = 1/72 in, xdpi and ydpi are stored in the frame's X display
12941 info. */
12949 /* Create the pixmap. */
12950 BLOCK_INPUT;
12955 UNBLOCK_INPUT;
12958 {
12961 }
12963 /* Call the loader to fill the pixmap. It returns a process object
12964 if successful. We do not record_unwind_protect here because
12965 other places in redisplay like calling window scroll functions
12966 don't either. Let the Lisp loader use `unwind-protect' instead. */
12987 window_and_pixmap_id,
12988 pixel_colors);
12989 UNGCPRO;
12991 }
12994 /* Kill the Ghostscript process that was started to fill PIXMAP on
12995 frame F. Called from XTread_socket when receiving an event
12996 telling Emacs that Ghostscript has finished drawing. */
12998 void
13000 Pixmap pixmap;
13002 {
13007 /* Find the image containing PIXMAP. */
13012 /* Should someone in between have cleared the image cache, for
13013 instance, give up. */
13017 /* Kill the GS process. We should have found PIXMAP in the image
13018 cache and its image should contain a process object. */
13024 /* On displays with a mutable colormap, figure out the colors
13025 allocated for the image by looking at the pixels of an XImage for
13026 img->pixmap. */
13029 {
13032 BLOCK_INPUT;
13034 /* Try to get an XImage for img->pixmep. */
13038 {
13041 /* Initialize the color table. */
13044 /* For each pixel of the image, look its color up in the
13045 color table. After having done so, the color table will
13046 contain an entry for each color used by the image. */
13049 {
13052 }
13054 /* Record colors in the image. Free color table and XImage. */
13060 here, we get a BadAccess later in x_clear_image when
13061 freeing the colors. */
13062 /* We have allocated colors once, but Ghostscript has also
13063 allocated colors on behalf of us. So, to get the
13064 reference counts right, free them once. */
13068 #endif
13069 }
13070 else
13074 UNBLOCK_INPUT;
13075 }
13077 /* Now that we have the pixmap, compute mask and transform the
13078 image if requested. */
13079 BLOCK_INPUT;
13081 UNBLOCK_INPUT;
13082 }
13086 \f
13087 /***********************************************************************
13088 Window properties
13089 ***********************************************************************/
13094 PROP and VALUE must be strings. FRAME nil or omitted means use the
13098 {
13101 Atom prop_atom;
13106 BLOCK_INPUT;
13112 /* Make sure the property is set when we return. */
13114 UNBLOCK_INPUT;
13119 }
13128 {
13132 Atom prop_atom;
13135 BLOCK_INPUT;
13139 /* Make sure the property is removed when we return. */
13141 UNBLOCK_INPUT;
13145 }
13151 If FRAME is nil or omitted, use the selected frame. Value is nil
13152 if FRAME hasn't a property with name PROP or if PROP has no string
13156 {
13160 Atom prop_atom;
13164 Atom actual_type;
13169 BLOCK_INPUT;
13176 {
13192 }
13194 UNBLOCK_INPUT;
13200 }
13203 \f
13204 /***********************************************************************
13205 Busy cursor
13206 ***********************************************************************/
13208 /* If non-null, an asynchronous timer that, when it expires, displays
13209 an hourglass cursor on all frames. */
13213 /* Non-zero means an hourglass cursor is currently shown. */
13217 /* Number of seconds to wait before displaying an hourglass cursor. */
13221 /* Default number of seconds to wait before displaying an hourglass
13222 cursor. */
13224 #define DEFAULT_HOURGLASS_DELAY 1
13226 /* Function prototypes. */
13232 /* Cancel a currently active hourglass timer, and start a new one. */
13234 void
13236 {
13238 EMACS_TIME delay;
13248 {
13249 Lisp_Object tem;
13253 }
13254 else
13260 #endif
13261 }
13264 /* Cancel the hourglass cursor timer if active, hide an hourglass
13265 cursor if shown. */
13267 void
13269 {
13271 {
13274 }
13278 }
13281 /* Timer function of hourglass_atimer. TIMER is equal to
13282 hourglass_atimer.
13284 Display an hourglass cursor on all frames by mapping the frames'
13285 hourglass_window. Set the hourglass_p flag in the frames'
13286 output_data.x structure to indicate that an hourglass cursor is
13287 shown on the frames. */
13289 static void
13292 {
13294 /* The timer implementation will cancel this timer automatically
13295 after this function has run. Set hourglass_atimer to null
13296 so that we know the timer doesn't have to be canceled. */
13300 {
13303 BLOCK_INPUT;
13307 {
13313 {
13315 XSetWindowAttributes attrs;
13323 InputOnly,
13324 CopyFromParent,
13326 }
13331 }
13334 UNBLOCK_INPUT;
13335 }
13336 #endif
13337 }
13340 /* Hide the hourglass cursor on all frames, if it is currently shown. */
13342 static void
13344 {
13347 {
13350 BLOCK_INPUT;
13352 {
13356 /* Watch out for newly created frames. */
13358 {
13361 /* Sync here because XTread_socket looks at the
13362 hourglass_p flag that is reset to zero below. */
13365 }
13366 }
13369 UNBLOCK_INPUT;
13370 }
13371 #endif
13372 }
13375 \f
13376 /***********************************************************************
13377 Tool tips
13378 ***********************************************************************/
13385 /* The frame of a currently visible tooltip. */
13387 Lisp_Object tip_frame;
13389 /* If non-nil, a timer started that hides the last tooltip when it
13390 fires. */
13392 Lisp_Object tip_timer;
13393 Window tip_window;
13395 /* If non-nil, a vector of 3 elements containing the last args
13396 with which x-show-tip was called. See there. */
13398 Lisp_Object last_show_tip_args;
13400 /* Maximum size for tooltips; a cons (COLUMNS . ROWS). */
13402 Lisp_Object Vx_max_tooltip_size;
13405 static Lisp_Object
13407 Lisp_Object frame;
13408 {
13409 Lisp_Object deleted;
13413 {
13416 }
13419 }
13422 /* Create a frame for a tooltip on the display described by DPYINFO.
13423 PARMS is a list of frame parameters. TEXT is the string to
13424 display in the tip frame. Value is the frame.
13426 Note that functions called here, esp. x_default_parameter can
13427 signal errors, for instance when a specified color name is
13428 undefined. We have to make sure that we're in a consistent state
13429 when this happens. */
13431 static Lisp_Object
13435 {
13438 Lisp_Object name;
13445 Lisp_Object buffer;
13450 /* Use this general default value to start with until we know if
13451 this frame has a specified name. */
13454 #ifdef MULTI_KBOARD
13456 #else
13458 #endif
13460 /* Get the name of the frame to use for resource lookup. */
13470 /* Make a frame without minibuffer nor mode-line. */
13487 /* By setting the output method, we're essentially saying that
13488 the frame is live, as per FRAME_LIVE_P. If we get a signal
13489 from this point on, x_destroy_window might screw up reference
13490 counts etc. */
13503 #ifdef MULTI_KBOARD
13505 #endif
13509 /* Set the name; the functions to which we pass f expect the name to
13510 be set. */
13512 {
13515 }
13516 else
13517 {
13520 /* use the frame's title when getting resources for this frame. */
13522 }
13524 /* Extract the window parameters from the supplied values
13525 that are needed to determine window geometry. */
13526 {
13527 Lisp_Object font;
13531 BLOCK_INPUT;
13532 /* First, try whatever font the caller has specified. */
13534 {
13538 else
13540 }
13542 /* Try out a font which we hope has bold and italic variations. */
13547 /* If those didn't work, look for something which will at least work. */
13550 UNBLOCK_INPUT;
13556 }
13560 /* This defaults to 2 in order to match xterm. We recognize either
13561 internalBorderWidth or internalBorder (which is what xterm calls
13562 it). */
13564 {
13565 Lisp_Object value;
13571 parms);
13572 }
13575 RES_TYPE_NUMBER);
13577 /* Also do the stuff which must be set before the window exists. */
13589 /* Init faces before x_default_parameter is called for scroll-bar
13590 parameters because that function calls x_set_scroll_bar_width,
13591 which calls change_frame_size, which calls Fset_window_buffer,
13592 which runs hooks, which call Fvertical_motion. At the end, we
13593 end up in init_iterator with a null face cache, which should not
13594 happen. */
13602 /* No fringes on tip frame. */
13609 {
13612 else
13614 }
13615 else
13616 {
13619 else
13621 }
13625 BLOCK_INPUT;
13627 UNBLOCK_INPUT;
13638 /* Dimensions, especially f->height, must be done via change_frame_size.
13639 Change will not be effected unless different from the current
13640 f->height. */
13647 /* Set up faces after all frame parameters are known. This call
13648 also merges in face attributes specified for new frames.
13650 Frame parameters may be changed if .Xdefaults contains
13651 specifications for the default font. For example, if there is an
13652 `Emacs.default.attributeBackground: pink', the `background-color'
13653 attribute of the frame get's set, which let's the internal border
13654 of the tooltip frame appear in pink. Prevent this. */
13655 {
13658 /* Set tip_frame here, so that */
13664 Qnil));
13665 }
13669 UNGCPRO;
13671 /* It is now ok to make the frame official even if we get an error
13672 below. And the frame needs to be on Vframe_list or making it
13673 visible won't work. */
13676 /* Now that the frame is official, it counts as a reference to
13677 its display. */
13680 /* Setting attributes of faces of the tooltip frame from resources
13681 and similar will increment face_change_count, which leads to the
13682 clearing of all current matrices. Since this isn't necessary
13683 here, avoid it by resetting face_change_count to the value it
13684 had before we created the tip frame. */
13687 /* Discard the unwind_protect. */
13689 }
13692 /* Compute where to display tip frame F. PARMS is the list of frame
13693 parameters for F. DX and DY are specified offsets from the current
13694 location of the mouse. WIDTH and HEIGHT are the width and height
13695 of the tooltip. Return coordinates relative to the root window of
13696 the display in *ROOT_X, and *ROOT_Y. */
13698 static void
13704 {
13707 /* User-specified position? */
13711 /* Move the tooltip window where the mouse pointer is. Resize and
13712 show it. */
13714 {
13715 POINT pt;
13717 BLOCK_INPUT;
13721 UNBLOCK_INPUT;
13722 }
13728 else
13729 {
13732 }
13737 /* It fits to the right of the pointer. */
13740 /* It fits to the left of the pointer. */
13742 else
13743 /* Put it left justified on the screen -- it ought to fit that way. */
13745 }
13750 A tooltip window is a small window displaying a string.
13752 FRAME nil or omitted means use the selected frame.
13754 PARMS is an optional list of frame parameters which can be
13755 used to change the tooltip's appearance.
13757 Automatically hide the tooltip after TIMEOUT seconds. TIMEOUT nil
13758 means use the default timeout of 5 seconds.
13760 If the list of frame parameters PARAMS contains a `left' parameter,
13761 the tooltip is displayed at that x-position. Otherwise it is
13762 displayed at the mouse position, with offset DX added (default is 5 if
13763 DX isn't specified). Likewise for the y-position; if a `top' frame
13764 parameter is specified, it determines the y-position of the tooltip
13765 window, otherwise it is displayed at the mouse position, with offset
13766 DY added (default is -10).
13768 A tooltip's maximum size is specified by `x-max-tooltip-size'.
13772 {
13791 else
13796 else
13801 else
13808 {
13816 {
13819 /* Only DX and DY have changed. */
13821 {
13825 }
13827 BLOCK_INPUT;
13831 /* Put tooltip in topmost group and in position. */
13836 /* Ensure tooltip is on top of other topmost windows (eg menus). */
13841 UNBLOCK_INPUT;
13843 }
13844 }
13846 /* Hide a previous tip, if any. */
13853 /* Add default values to frame parameters. */
13864 parms);
13866 /* Block input until the tip has been fully drawn, to avoid crashes
13867 when drawing tips in menus. */
13868 BLOCK_INPUT;
13870 /* Create a frame for the tooltip, and record it in the global
13871 variable tip_frame. */
13875 /* Set up the frame's root window. */
13884 {
13887 }
13888 else
13889 {
13892 }
13898 /* Display the tooltip text in a temporary buffer. */
13907 /* Compute width and height of the tooltip. */
13910 {
13915 /* Stop at the first empty row at the end. */
13919 /* Let the row go over the full width of the frame. */
13923 calculated for some tooltips. */
13924 /* There's a glyph at the end of rows that is use to place
13925 the cursor there. Don't include the width of this glyph. */
13927 {
13930 }
13931 else
13932 #endif
13935 /* TODO: find why tips do not draw along baseline as instructed. */
13938 }
13940 /* Add the frame's internal border to the width and height the X
13941 window should have. */
13945 /* Move the tooltip window where the mouse pointer is. Resize and
13946 show it. */
13949 {
13950 /* Adjust Window size to take border into account. */
13951 RECT rect;
13958 /* Position and size tooltip, and put it in the topmost group. */
13963 /* Ensure tooltip is on top of other topmost windows (eg menus). */
13968 /* Let redisplay know that we have made the frame visible already. */
13972 }
13974 /* Draw into the window. */
13978 UNBLOCK_INPUT;
13980 /* Restore original current buffer. */
13984 start_timer:
13985 /* Let the tip disappear after timeout seconds. */
13989 UNGCPRO;
13991 }
13997 ()
13998 {
14003 /* Return quickly if nothing to do. */
14020 {
14023 }
14025 UNGCPRO;
14027 }
14030 \f
14031 /***********************************************************************
14032 File selection dialog
14033 ***********************************************************************/
14039 Use a file selection dialog.
14040 Select DEFAULT-FILENAME in the dialog's file selection box, if
14044 {
14057 /* Create the dialog with PROMPT as title, using DIR as initial
14058 directory and using "*" as pattern. */
14065 {
14074 else
14075 {
14076 file_name_only++;
14078 /* If default_file_name is a directory, don't use the open
14079 file dialog, as it does not support selecting
14080 directories. */
14083 }
14087 }
14088 else
14092 {
14093 OPENFILENAME file_details;
14095 /* Prevent redisplay. */
14097 BLOCK_INPUT;
14102 /* Undocumented Bug in Common File Dialog:
14103 If a filter is not specified, shell links are not resolved. */
14115 {
14118 }
14119 else
14122 UNBLOCK_INPUT;
14124 }
14125 /* Open File dialog will not allow folders to be selected, so resort
14126 to minibuffer completing reads for directories. */
14127 else
14132 UNGCPRO;
14134 /* Make "Cancel" equivalent to C-g. */
14139 }
14142 \f
14143 /***********************************************************************
14144 w32 specialized functions
14145 ***********************************************************************/
14152 {
14154 CHOOSEFONT cf;
14155 LOGFONT lf;
14156 TEXTMETRIC tm;
14157 HDC hdc;
14158 HANDLE oldobj;
14168 /* Unless include_proportional is non-nil, limit the selection to
14169 monospaced fonts. */
14175 /* Initialize as much of the font details as we can from the current
14176 default font. */
14181 {
14189 }
14197 }
14202 Some useful values for command are #xf030 to maximise frame (#xf020
14203 to minimize), #xf120 to restore frame to original size, and #xf100
14204 to activate the menubar for keyboard access. #xf140 activates the
14205 screen saver if defined.
14210 {
14218 }
14222 This is a wrapper around the ShellExecute system function, which
14223 invokes the application registered to handle OPERATION for DOCUMENT.
14224 OPERATION is typically \"open\", \"print\" or \"explore\" (but can be
14225 nil for the default action), and DOCUMENT is typically the name of a
14226 document file or URL, but can also be a program executable to run or
14227 a directory to open in the Windows Explorer.
14229 If DOCUMENT is a program executable, PARAMETERS can be a string
14230 containing command line parameters, but otherwise should be nil.
14232 SHOW-FLAG can be used to control whether the invoked application is hidden
14233 or minimized. If SHOW-FLAG is nil, the application is displayed normally,
14234 otherwise it is an integer representing a ShowWindow flag:
14236 0 - start hidden
14237 1 - start normally
14238 3 - start maximized
14242 {
14243 Lisp_Object current_dir;
14247 /* Encode filename and current directory. */
14262 }
14264 /* Lookup virtual keycode from string representing the name of a
14265 non-ascii keystroke into the corresponding virtual key, using
14266 lispy_function_keys. */
14267 static int
14269 {
14278 }
14280 /* Convert a one-element vector style key sequence to a hot key
14281 definition. */
14282 static int
14284 Lisp_Object key;
14285 {
14286 /* Copied from Fdefine_key and store_in_keymap. */
14305 UNGCPRO;
14310 /* Work out the base key and the modifiers. */
14312 {
14319 }
14321 {
14323 /* Many ascii characters are their own virtual key code. */
14325 }
14334 /* Supply defs missing from mingw32. */
14335 #ifndef MOD_ALT
14336 #define MOD_ALT 0x0001
14337 #define MOD_CONTROL 0x0002
14338 #define MOD_SHIFT 0x0004
14339 #define MOD_WIN 0x0008
14340 #endif
14342 /* Convert lisp modifiers to Windows hot-key form. */
14349 }
14354 Certain key combinations like Alt-Tab are reserved for system use on
14355 Windows, and therefore are normally intercepted by the system. However,
14356 most of these key combinations can be received by registering them as
14357 hot-keys, overriding their special meaning.
14359 KEY must be a one element key definition in vector form that would be
14360 acceptable to `define-key' (e.g. [A-tab] for Alt-Tab). The meta
14361 modifier is interpreted as Alt if `w32-alt-is-meta' is t, and hyper
14362 is always interpreted as the Windows modifier keys.
14366 Lisp_Object key;
14367 {
14371 {
14372 /* Reuse an empty slot if possible. */
14375 /* Safe to add new key to list, even if we have focus. */
14378 else
14381 /* Notify input thread about new hot-key definition, so that it
14382 takes effect without needing to switch focus. */
14385 }
14388 }
14394 Lisp_Object key;
14395 {
14396 Lisp_Object item;
14404 {
14405 /* Notify input thread about hot-key definition being removed, so
14406 that it takes effect without needing focus switch. */
14409 {
14410 MSG msg;
14412 }
14414 }
14416 }
14421 ()
14422 {
14424 }
14430 Lisp_Object hotkeyid;
14431 {
14433 Lisp_Object key;
14442 else
14456 }
14461 KEY can be `capslock', `kp-numlock', or `scroll'.
14462 If the optional parameter NEW-STATE is a number, then the state of KEY
14466 {
14475 else
14483 {
14484 MSG msg;
14487 }
14489 }
14490 \f
14493 Value is a list of floats (TOTAL FREE AVAIL), where TOTAL is the total
14494 storage of the file system, FREE is the free storage, and AVAIL is the
14495 storage available to a non-superuser. All 3 numbers are in bytes.
14498 Lisp_Object filename;
14499 {
14508 /* Determining the required information on Windows turns out, sadly,
14509 to be more involved than one would hope. The original Win32 api
14510 call for this will return bogus information on some systems, but we
14511 must dynamically probe for the replacement api, since that was
14512 added rather late on. */
14513 {
14519 /* On Windows, we may need to specify the root directory of the
14520 volume holding FILENAME. */
14524 /* find the root name of the volume if given */
14526 {
14531 }
14533 {
14536 do
14537 {
14541 }
14546 }
14549 {
14550 LARGE_INTEGER availbytes;
14551 LARGE_INTEGER freebytes;
14552 LARGE_INTEGER totalbytes;
14561 }
14562 else
14563 {
14564 DWORD sectors_per_cluster;
14565 DWORD bytes_per_sector;
14566 DWORD free_clusters;
14567 DWORD total_clusters;
14580 }
14581 }
14584 }
14585 \f
14586 /***********************************************************************
14587 Initialization
14588 ***********************************************************************/
14590 void
14592 {
14595 /* This is zero if not using MS-Windows. */
14598 /* TrackMouseEvent not available in all versions of Windows, so must load
14599 it dynamically. Do it once, here, instead of every time it is used. */
14694 /* This is the end of symbol initialization. */
14696 /* Text property `display' should be nonsticky by default. */
14697 Vtext_property_default_nonsticky
14733 When non-nil, for example, alt pressed and released and then space will
14761 Value is a number between 0 and 255.
14763 Phantom key presses are generated in order to stop the system from
14764 acting on \"Windows\" key events when `w32-pass-lwindow-to-system' or
14766 /* Although 255 is technically not a valid key code, it works and
14767 means that this hack won't interfere with any real key code. */
14785 The value can be hyper, super, meta, alt, control or shift for the
14786 respective modifier, or nil to see Scroll Lock as the key `scroll'.
14793 The value can be hyper, super, meta, alt, control or shift for the
14794 respective modifier, or nil to appear as the key `lwindow'.
14801 The value can be hyper, super, meta, alt, control or shift for the
14802 respective modifier, or nil to appear as the key `rwindow'.
14809 The value can be hyper, super, meta, alt, control or shift for the
14810 respective modifier, or nil to appear as the key `apps'.
14825 The value is the minimum time in milliseconds that must elapse between
14826 left/right button down events before they are considered distinct events.
14827 If both mouse buttons are depressed within this interval, a middle mouse
14834 The value is the minimum time in milliseconds that must elapse between
14835 successive mouse move (or scroll bar drag) events before they are
14842 Recent versions of Windows support mice with up to five buttons.
14843 Since most applications don't support these extra buttons, most mouse
14844 drivers will allow you to map them to functions at the system level.
14845 If this variable is non-nil, Emacs will pass them on, allowing the
14857 Changing the value does not affect existing frames
14863 `x-get-resource' uses this as the first component of the instance name
14864 when requesting resource values.
14865 Emacs initially sets `x-resource-name' to the name under which Emacs
14866 was invoked, or to the value specified with the `-name' or `-rn'
14876 This variable takes effect when you create a new frame
14892 This variable takes effect when you create a new frame
14899 This variable takes effect when you create a new frame
14914 Emacs doesn't try to figure this out; this is always nil
14916 /* We don't have any way to find this out, so set it to nil
14917 and maybe the user would like to set it to t. */
14924 Since Emacs gets width of a font matching with this regexp from
14925 PIXEL_SIZE field of the name, font finding mechanism gets faster for
14926 such a font. This is especially effective for such large fonts as
14932 When an image has not been displayed this many seconds, remove it
14933 from the image cache. Value must be an integer or nil with nil
14945 Default is nil, which allows old fontnames that are not XLFD compliant,
14946 and allows third-party CJK display to work by specifying false charset
14947 fields to trick Emacs into translating to Big5, SJIS etc.
14948 Setting this to t will prevent wrong fonts being selected when
14955 Set this to nil to get the old behaviour for repainting; this should
14962 Each entry should be of the form:
14964 (CHARSET_NAME . (WINDOWS_CHARSET . CODEPAGE))
14966 where CHARSET_NAME is a string used in font names to identify the charset,
14967 WINDOWS_CHARSET is a symbol that can be one of:
14968 w32-charset-ansi, w32-charset-default, w32-charset-symbol,
14969 w32-charset-shiftjis, w32-charset-hangeul, w32-charset-gb2312,
14970 w32-charset-chinesebig5,
14971 #ifdef JOHAB_CHARSET
14972 w32-charset-johab, w32-charset-hebrew,
14973 w32-charset-arabic, w32-charset-greek, w32-charset-turkish,
14974 w32-charset-vietnamese, w32-charset-thai, w32-charset-easteurope,
14975 w32-charset-russian, w32-charset-mac, w32-charset-baltic,
14976 #endif
14977 #ifdef UNICODE_CHARSET
14978 w32-charset-unicode,
14979 #endif
14980 or w32-charset-oem.
14981 CODEPAGE should be an integer specifying the codepage that should be used
14982 to display the character set, t to do no translation and output as Unicode,
14983 or nil to do no translation and output as 8 bit (or multibyte on far-east
15002 #ifdef JOHAB_CHARSET
15003 {
15030 }
15031 #endif
15033 #ifdef UNICODE_CHARSET
15034 {
15042 #endif
15049 #endif
15074 /* W32 specific functions */
15092 /* Setting callback functions for fontset handler. */
15096 And the pointer assigned has the wrong type, anyway. */
15098 #endif
15107 /* Images. */
15139 #if HAVE_XPM
15142 #endif
15144 #if HAVE_JPEG
15147 #endif
15149 #if HAVE_TIFF
15152 #endif
15154 #if HAVE_GIF
15157 #endif
15159 #if HAVE_PNG
15162 #endif
15166 #if GLYPH_DEBUG
15169 #endif
15185 }
15188 void
15190 {
15199 #if HAVE_XPM
15201 #endif
15203 #if HAVE_JPEG
15205 #endif
15207 #if HAVE_TIFF
15209 #endif
15211 #if HAVE_GIF
15213 #endif
15215 #if HAVE_PNG
15217 #endif
15219 }
15221 #undef abort
15223 void
15225 {
15231 MB_ICONEXCLAMATION | MB_TASKMODAL
15234 {
15244 }
15245 }
15247 /* For convenience when debugging. */
15248 int
15250 {
15252 }